JP6904601B2 - Breath gas analyzer and method - Google Patents

Description

The present invention relates to an exhaled gas analyzer, and more particularly to a calibration of gas concentration.

Conventionally, an exhaled gas analyzer is used for evaluation of biological functions such as respiratory metabolism measurement and diagnosis of illness to obtain an index related to respiratory metabolism by analyzing the gas concentration and gas amount of the gas to be measured in the respiratory air of the subject. It is a thing. Further, conventionally, as such an exhaled gas analyzer, a pulsed calibration gas is discharged many times at regular intervals, and the delay time td measured by delaying the gas concentration with respect to the flow rate is averaged to cause fluctuations and the like. An exhaled gas analyzer has been proposed which can eliminate the error factor due to the above and accurately obtain the delay time td (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-18622

Conventionally, in an exhaled gas analyzer, a calibration gas having a known gas concentration (for example, an oxygen concentration of 15%, a carbon dioxide concentration of 5%, etc.) and an atmospheric gas are used to obtain a measured value and a true value of the measured gas. The gas concentration was calibrated by obtaining the relationship (relational expression). At this time, the composition of the atmospheric gas is based on the premise that the gas composition has a certain known concentration, such as an oxygen concentration of 20.93% and a carbon dioxide concentration of 0.04%. The relationship between the true value) and the measured value was sought.

However, especially when the usage environment is indoors, the gas concentration in the atmosphere, which is generally known and considered to be constant, is not constant due to environmental factors such as the indoor size and the number of people in the room. Concentrations tend to increase due to environmental factors rather than 0.04%. Since such a change in the atmospheric gas concentration due to environmental factors is not taken into consideration when performing the above calibration, there is a problem that the measurement (calculation) accuracy of the parameter using the gas concentration is lowered.

In view of the above problems, it is an object of the present disclosure to obtain highly accurate breath gas analysis data (parameters using gas concentration) by accurately calibrating the gas concentration in the breath gas analyzer.

An example of the present disclosure is an exhaled gas concentration measuring means for measuring the gas concentration of a predetermined gas which is at least one of oxygen and carbon dioxide in exhaled breath, and a gas of a predetermined gas which is at least one of oxygen and carbon dioxide in air gas. Using the atmospheric gas concentration measuring means for measuring the concentration and the atmospheric gas and the calibration gas having a known gas concentration, the relational expression between the gas concentration measured value by the breath gas concentration measuring means and the true gas concentration value is calculated. A calibration means for calibrating the gas concentration of the predetermined gas in exhaled breath based on the relational expression is provided, and the calibration means measures the gas concentration of the predetermined gas in the atmospheric gas measured by the atmospheric gas concentration measuring means. , An exhaled gas analyzer that calculates the relational expression as the true value of the gas concentration of the predetermined gas in the atmospheric gas.
Is.

The present disclosure can be understood as a method executed by an information processing device, a system, a computer, or a program executed by a computer. The present disclosure can also be grasped as if such a program is recorded on a recording medium that can be read by a computer, other device, a machine, or the like. Here, a recording medium that can be read by a computer or the like is a recording medium that can be read from a computer or the like by accumulating information such as data or programs by electrical, magnetic, optical, mechanical or chemical action. say.

According to the present disclosure, by accurately calibrating the gas concentration in the breath gas analyzer, it is possible to obtain highly accurate breath gas analysis data (parameters using the gas concentration).

It is the schematic which shows the structure of the exhaled gas analyzer which concerns on embodiment. It is a figure which shows the outline of the functional structure of the breath gas analyzer which concerns on embodiment. It is a flowchart which shows the outline of the flow of the calibration process of the gas concentration which concerns on embodiment. It is a figure which shows the relationship between the measured value and the true value of the carbon dioxide concentration which concerns on embodiment. It is a figure which shows the relationship between the measured value and the true value of the oxygen concentration which concerns on embodiment. It is a figure which shows the relationship between the measured value of the conventional carbon dioxide concentration and the true value (without considering the fluctuation of the atmospheric gas concentration). It is a schematic diagram which shows the structure of the conventional breath gas analyzer. It is a figure which shows the waveform of the output voltage at the time of gas concentration calibration in the conventional breath gas analyzer. It is a figure which shows the relationship between the measured value and the true value of the carbon dioxide concentration in the conventional breath gas analyzer.

Hereinafter, embodiments of the breath gas analyzer and method according to the present disclosure will be described with reference to the drawings. However, the embodiment described below is an example of the embodiment, and the breath gas analyzer and method according to the present disclosure are not limited to the specific configuration described below. In the implementation, a specific configuration according to the embodiment may be appropriately adopted, and various improvements and modifications may be made.

In the present embodiment, the embodiment when the breath gas analyzer and the method according to the present disclosure are carried out in the breath gas analyzer for measuring respiratory metabolism will be described. However, the exhaled gas analyzer according to the present disclosure can be widely used for a technique for analyzing the gas concentration, the amount of gas, etc. of the gas to be measured in the respiratory air, and the subject of the present disclosure is the present implementation. It is not limited to the example shown in the form.

<Previous technology>
Hereinafter, an example of a gas concentration calibration method in a conventional breath gas analyzer will be described with reference to the drawings. As the calibration gas used at the time of calibration, a calibration gas having a predetermined gas concentration having a gas composition different from that of the atmospheric gas and the atmospheric gas is usually used. Conventionally, in a breath analyzer, the gas concentration is calibrated by taking in the actual atmosphere for the atmospheric gas which is the calibration gas and using the gas cylinder related to the calibration mixed gas for the calibration gas which is the calibration gas. ing.

FIG. 7 is a schematic view showing the configuration of a conventional breath gas analyzer. The exhaled gas analyzer 91 includes a main body 92, a flow sensor 93, a calibrator 94, and an information processing device 95. Further, the main body 92 includes an oxygen sensor 92A and a carbon dioxide sensor 92B.

The main body 92 is the main body of the breath gas analyzer 91, and includes sensors for measuring the gas concentration of the gas to be measured contained in the breath of the subject, which is exemplified by the oxygen sensor 92A and the carbon dioxide sensor 92B. The main body 92 is connected to the flow sensor 93, and by introducing the exhaled breath of the subject collected by the breathing air collecting unit such as the breathing air mask connected to the flow sensor 93 into the main body 92, the exhaled air is in the exhaled air. Measure the gas concentration of the gas to be measured. Further, the main body 92 is connected to a calibration device 94 that supplies a calibration gas used when calibrating the gas concentration, and the calibration gas is introduced into the main body 92 from the calibrator 94 via a sampling tube or the like for calibration. Measure the gas concentration of the gas to be measured in the gas. Further, the main body 92 is provided with a pump or the like that takes in a certain amount of gas, and by taking in the atmospheric gas through the sampling tube or the like by the pump, the gas concentration of the gas to be measured in the atmospheric gas is measured.

Further, the main body 92 is an A / D converter that converts the flow velocity (flow rate) of gas breathing air measured by the flow sensor 93 into an electric signal, an arithmetic unit composed of a CPU, and a storage device such as a ROM, RAM, and hard disk. A predetermined program stored (stored) in the storage device and a communication device such as a wireless communication device or a wired communication device are provided, and the program stored in the storage device is executed by the CPU to cause the main body 92. Each function it has is executed.

The oxygen sensor 92A is a sensor that measures the concentration of oxygen contained in the calibration gas used when calibrating the exhaled breath and the gas concentration, and the carbon dioxide sensor 92B is the concentration of carbon dioxide contained in the exhaled breath and the calibration gas. It is a sensor that measures.

The flow sensor 93 is connected to a respiratory collection unit (not shown) such as a respiratory mask, and measures the flow velocity (flow rate) of the respiratory air of the subject collected by the respiratory air collection unit.

The calibrator 94 is connected to the main body 92 and supplies the calibration gas used for calibrating the gas concentration to the sensor for measuring the gas to be measured. Specifically, the calibrator 94 supplies the calibration gas in the gas cylinder connected to the calibrator to the oxygen sensor 92A and the carbon dioxide sensor 92B of the main body 92 by opening the solenoid valve in the calibrator 94. .. Further, the calibrator 94 includes an arithmetic unit composed of a CPU, a storage device such as a ROM, RAM, and a hard disk, a predetermined program stored (stored) in the storage device, a calibrator gas supply device such as an electromagnetic valve and a gas tube, and A communication device such as a wireless communication device or a wired communication device is provided, and each function of the calibrator 94 is executed by executing a program stored in the storage device by the CPU.

The information processing device 95 calibrates the gas concentration by obtaining the relationship (relational expression) between the measured gas concentration value and the true gas concentration value in the oxygen sensor 92A and the carbon dioxide sensor 92B. Further, the information processing apparatus 95 calculates various exhaled gas analysis data (parameters using gas concentration and gas amount) by using the flow velocity (flow rate) of breathing air, the measured value of oxygen concentration, the measured value of carbon dioxide concentration, and the like. do. The information processing device 95 stores in an input device for inputting data, an output device for outputting processed data, a computing device composed of a CPU, a storage device such as a ROM, RAM, and a hard disk, and a storage device ( It is equipped with a predetermined program stored (stored) and a communication device such as a wireless communication device or a wired communication device, and the CPU executes the program stored in the storage device to perform each function of the information processing device 95. Will be executed.

Specifically, the information processing device 95 is connected to or can be connected to the main body 92, and the calibration gas measured from the main body 92 by the oxygen sensor 92A and the carbon dioxide sensor 92B at the time of gas concentration calibration. Receives the gas concentration measurement value of oxygen contained in and the gas concentration measurement value of carbon dioxide. In the information processing apparatus 95, the gas concentration is calibrated by obtaining the relational expression between the true value of the gas concentration and the measured value based on these measured values.

Further, the information processing device 95 measures the oxygen concentration in exhaled breath, the carbon dioxide concentration measurement value, and the respiratory air flow rate measurement measured by the flow sensor 93 from the main body 92 by the oxygen sensor 92A and the carbon dioxide sensor 92B. Receive a value. In the information processing apparatus 95, the true values of each gas concentration of oxygen and carbon dioxide in the exhaled breath are obtained by applying these measured values to the above relational expression, and by using the true gas concentration values, the minute oxygen intake amount. , Calculate exhaled gas analysis data such as minute carbon dioxide excretion and minute expiratory ventilation.

The "true value" in the present embodiment is a "value assumed to be a true value", that is, a "value that can be measured by a gas concentration measuring unit that does not cause a measurement error", and is a value treated as an actually measured value. means .

FIG. 8 is a diagram showing a waveform of an output voltage at the time of gas concentration calibration in a conventional breath gas analyzer. As shown in FIG. 8, the atmosphere is taken in for about 10 seconds for the first time, and then the calibration gas is taken in. In the conventional breath gas analyzer, the real atmosphere (air) is first taken into the main body 92, and the oxygen sensor 92A and the carbon dioxide sensor 92B measure the oxygen concentration and the carbon dioxide concentration in the atmosphere, respectively, per unit time. The average voltage value (or gas concentration) is output. In a conventional breath gas analyzer, as described in detail below, the true value of the gas concentration in the real atmosphere is a known concentration (for example, oxygen concentration is 20.93%, carbon dioxide concentration is 0.04%). As a result, a relational expression with the measured value is obtained.

Next, the calibration gas is taken into the main body 92 by the calibration device 94, and the oxygen sensor 92A and the carbon dioxide sensor 92B measure the oxygen concentration and the carbon dioxide concentration in the calibration gas, respectively, as the average voltage value per unit time ( Or gas concentration) is output. Here, the calibration gas is a calibration gas having a predetermined gas concentration having a gas composition different from that of the atmospheric gas, and has a known gas concentration such as, for example, an oxygen concentration of about 15% and a carbon dioxide concentration of about 5%. Illustrated in calibration gas.

Then, in the information processing apparatus 95, the relationship (relational expression) between the measured gas concentration value and the true gas concentration value is obtained. Specifically, for each of oxygen (sensor) and carbon dioxide (sensor), the measured values at two points, that is, when measuring atmospheric gas (measurement point A) and when measuring calibration gas (measurement point B), and their true values are used. Then, a linear function (y = ax + b) that passes through the two points is obtained.

FIG. 9 is a diagram showing the relationship between the measured value and the true value of the carbon dioxide concentration in the conventional breath gas analyzer. In FIG. 9, the horizontal axis (x) is the true value (%) of the gas concentration, and the vertical axis (y) is the value (output voltage) (V) measured by the sensor. Further, the relationship between the measured value of the oxygen concentration and the true value is also obtained in the same manner as in FIG.

As shown in FIG. 9, at the time of atmospheric gas measurement (measurement point A), the true value of the carbon dioxide concentration is 0.04%, which is a known concentration, and the measured value is 2350 mV. Similarly, at the time of measuring the calibration gas (measurement point B), the true value of the carbon dioxide concentration is 5.0%, which is a known concentration, and the measured value is 2700 mV. In the information processing apparatus 95, by using these measured values and true values, a linear function (y = ax + b, a and b are constants) that pass through the above two points can be obtained. Then, for example, in the case of carbon dioxide, the exhaled carbon dioxide concentration between 0.04% and 5.0% is determined by the output voltage of the carbon dioxide sensor 92B at the time of exhaled gas measurement. Specifically, by applying the output voltage value indicating the carbon dioxide concentration in the exhaled gas measured by the carbon dioxide sensor 92B to y of the relational expression obtained above, the true value of the carbon dioxide concentration in the exhaled breath (x). ) Can be obtained.

In this way, in the conventional breath gas analyzer, when the relationship between the measured value of the gas concentration and the true value is obtained, the true value of the gas concentration of the atmospheric gas is assumed to be a certain known concentration, which is an environmental factor. Therefore, when the gas concentration in the atmosphere, for example, the carbon dioxide concentration is rising instead of 0.04%, there is a problem that the relational expression obtained above is insufficient (poor accuracy). Further, if the relational expression cannot be obtained with high accuracy, there is a problem that the calculation accuracy of the parameter using the gas concentration calculated by using the relational expression is lowered.

<System configuration>
FIG. 1 is a schematic view showing a configuration of an exhaled gas analyzer according to the present embodiment. The exhaled gas analyzer 1 according to the present embodiment includes a main body 2, a flow sensor 3, a calibrator 4, and an information processing device 5. Further, the main body 2 includes an oxygen sensor 2A and a carbon dioxide sensor 2B, and the calibrator 4 includes a carbon dioxide sensor 4A. Hereinafter, the hardware configuration of the breath gas analyzer 1 will be described, but the specific hardware configuration of the breath gas analyzer 1 can be omitted, replaced, or added as appropriate depending on the embodiment. Further, the main body 2, the calibrator 4, and the information processing device 5 are not limited to a device composed of a single housing, and may be realized by a plurality of devices using so-called cloud computing, distributed computing technology, or the like.

The main body 2 is the main body of the exhaled gas analyzer 1, and includes a sensor for measuring the gas concentration of the gas to be measured contained in the exhaled breath of the subject, which is exemplified by the oxygen sensor 2A and the carbon dioxide sensor 2B. The main body 2 is connected to the flow sensor 3, and by introducing the exhaled breath of the subject collected by the breathing air collecting unit such as the breathing air mask connected to the flow sensor 3 into the main body 2, the exhalation is carried out. Measure the gas concentration of the gas to be measured. Further, the main body 2 is connected to a calibration device 4 that supplies a calibration gas (a calibration gas having a predetermined gas concentration different from that of atmospheric gas) used when calibrating the gas concentration, and the calibration tube 4 or the like is connected to the calibration device 4. By introducing the calibration gas into the main body 2 via the above, the gas concentration of the measurement target gas in the calibration gas is measured. Further, the main body 2 is provided with a pump or the like that takes in a certain amount of gas, and by taking in the atmospheric gas through the sampling tube or the like by the pump, the gas concentration of the gas to be measured in the atmospheric gas is measured.

Further, the main body 2 includes an A / D converter that converts the flow velocity (flow rate) of breathing air measured by the flow sensor 3 into an electric signal, an arithmetic unit composed of a CPU, a storage device such as a ROM, RAM, and a hard disk. A predetermined program stored (stored) in the storage device and a communication device such as a wireless communication device or a wired communication device are provided, and the main body 2 has a program stored in the storage device when the CPU executes the program. Each function is executed.

The oxygen sensor 2A is a sensor that measures the concentration of oxygen contained in the exhaled breath and the calibration gas, and the carbon dioxide sensor 2B is a sensor that measures the concentration of carbon dioxide contained in the exhaled breath and the calibration gas. The carbon dioxide sensor 2B is, for example, a non-dispersive infrared absorption type (NDIR) sensor. In the present embodiment, the main body 2 is provided with both the oxygen sensor 2A and the carbon dioxide sensor 2B, but the present invention is not limited to this, and one of the sensors may be provided.

The flow sensor 3 is connected to a respiratory collection unit (not shown) such as a respiratory mask, and measures the flow velocity (flow rate) of the respiratory air of the subject collected by the respiratory air collection unit.

The calibrator 4 includes a sensor that measures the gas concentration of the gas to be measured contained in the atmospheric gas, which is exemplified by the carbon dioxide sensor 4A. The carbon dioxide sensor 4A is, for example, a non-dispersive infrared absorption type (NDIR) sensor, and measures the gas concentration of carbon dioxide contained in the atmospheric gas inside the calibrator 4 (or outside the calibrator 4). Further, the calibrator 4 is connected to the main body 2 and supplies the calibrator gas to the sensor that measures the gas to be measured. Specifically, the calibrator 4 supplies the calibration gas to the oxygen sensor 2A and the carbon dioxide sensor 2B of the main body 2 by opening the solenoid valve in the calibrator 4. The method of supplying the calibration gas and the method of introducing the atmospheric gas are not limited to the methods shown in the present embodiment, as long as the gas to be measured is supplied (introduced) to each sensor. , Various methods may be adopted.

Further, the calibrator 4 includes an arithmetic unit composed of a CPU, a storage device such as a ROM, RAM, and a hard disk, a predetermined program stored (stored) in the storage device, a calibration gas supply device such as an electromagnetic valve and a gas tube, and a calibrator. It is equipped with a communication device such as a wireless communication device or a wired communication device, and when a program stored in the storage device is executed by the CPU, each function of the calibrator 4 is executed.

The carbon dioxide sensor 4A is a sensor that measures the gas concentration of carbon dioxide in the atmospheric gas, and due to its nature, it does not have to be a high-speed type sensor that measures exhaled breath. Therefore, the carbon dioxide sensor 4A is a general-purpose type. Carbon dioxide sensor may be used. This general-purpose type carbon dioxide sensor 4A has higher gas concentration measurement accuracy than the high-speed type carbon dioxide sensor 2B for breath measurement, and can measure the gas concentration of atmospheric gas with high accuracy. For example, the carbon dioxide sensor 2B for breath measurement has an error range of ± 0.26% for a gas concentration of 0.04%, whereas the carbon dioxide sensor 4A has an error range of ± 0. For a gas concentration of 0.04%. It is 075%.

Further, since the general-purpose type carbon dioxide sensor 4A is relatively cheaper than the carbon dioxide sensor 2B for exhalation, the carbon dioxide sensor 4A is also mounted on the exhaled gas analyzer 1 (calibrator 4). Compared with the case where a carbon dioxide sensor of the same type as 2B is installed, it is possible to reduce the cost. Further, by mounting two types of carbon dioxide sensors, a carbon dioxide sensor 2B and a carbon dioxide sensor 4A, on the breath gas analyzer 1, a cross check is performed by these two carbon dioxide sensors, and a sensor failure or the like is estimated. It is also possible. For example, when the values measured by the two sensors differ from each other by more than the measurement accuracy, it is possible to estimate that the sensor has failed.

In the present embodiment, the carbon dioxide sensor 4A for measuring the gas concentration of the atmospheric gas is mounted on the calibrator 4, but the present invention is not limited to this, and the carbon dioxide sensor 4A may be mounted on the main body 2. Further, the main body 2 and the calibrator 4 may be integrated (same device) instead of a separate body (separate device). Further, in the present embodiment, the sensor provided in the calibrator 4 for measuring the gas concentration of atmospheric gas is a carbon dioxide sensor, but the present invention is not limited to this, and even if it is an oxygen sensor, the oxygen sensor and Both carbon dioxide sensors may be provided.

The information processing device 5 calibrates the gas concentration by obtaining the relationship (relational expression) between the measured gas concentration value and the true gas concentration value in the oxygen sensor 2A and the carbon dioxide sensor 2B. Further, the information processing apparatus 5 calculates various exhaled gas analysis data (parameters using gas concentration and gas amount) by using the flow velocity (flow rate) of breathing air, the measured value of oxygen concentration, the measured value of carbon dioxide concentration, and the like. do. The information processing device 5 stores in an input device for inputting data, an output device for outputting processed data, a computing device composed of a CPU, a storage device such as a ROM, RAM, and a hard disk, and a storage device ( It is equipped with a predetermined program stored (stored) and a communication device such as a wireless communication device or a wired communication device, and the CPU executes the program stored in the storage device to perform each function of the information processing device 5. Will be executed.

Specifically, the information processing device 5 is connected to the calibration device 4, and the carbon dioxide gas contained in the calibration gas (atmospheric gas) measured from the calibration device 4 by the carbon dioxide sensor 4A at the time of gas concentration calibration. Receive the concentration measurement value. Further, the information processing device 5 is connected to or can be connected to the main body 2, and the calibration gas (atmospheric gas) measured from the main body 2 by the oxygen sensor 2A and the carbon dioxide sensor 2B at the time of gas concentration calibration. And the gas concentration measurement value of oxygen contained in the calibration gas) and the gas concentration measurement value of carbon dioxide are received. In the information processing apparatus 5, the gas concentration is calibrated by obtaining the relational expression between the true value of the gas concentration and the measured value based on these measured values.

In addition, the information processing device 5 has an oxygen concentration measured value in exhaled breath, a carbon dioxide concentration measured value, and a respiratory air flow velocity measured by the flow sensor 3 measured by the oxygen sensor 2A and the carbon dioxide sensor 2B from the main body 2. Flow rate) Receive the measured value. In the information processing apparatus 5, the true values of each gas concentration of oxygen and carbon dioxide in the exhaled breath are obtained by applying these measured values to the above relational expression, and the true values of the gas concentrations are used to obtain the minute oxygen intake. , Calculate exhaled gas analysis data such as minute carbon dioxide excretion and minute expiratory ventilation.

FIG. 2 is a diagram showing an outline of the functional configuration of the exhaled gas analyzer 1 according to the present embodiment. In the present embodiment, each function included in the main body 2, the flow sensor 3, the calibrator 4, and the information processing device 5 is executed by the CPU, which is a general-purpose processor, but some or all of these functions may be one or more. It may be executed by a dedicated processor of.

In the main body 2, the program stored in the storage device is executed by the CPU, and each hardware provided in the main body 2 is controlled, so that the control unit 21 and the flow that control each hardware such as a sensor in the main body 2 A / D conversion unit 22 that converts the flow velocity (flow rate) of breathing air measured by the sensor 3 into an electric signal, oxygen concentration measurement unit 23 that measures the gas concentration of oxygen contained in exhaled breath and calibration gas, exhaled air and A carbon dioxide concentration measuring unit 24 that measures the gas concentration of carbon dioxide contained in the calibration gas, a storage unit 25 that stores the measured values of respiratory air flow rate (flow rate), oxygen concentration, carbon dioxide concentration, etc., and communication of various data ( It functions as a communication unit 26 or the like that performs transmission / reception).

The oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 are examples of the “breath gas concentration measuring means” of the present invention. In the exhaled gas analysis for measuring respiratory metabolism, only the gas concentration of a predetermined gas, which is at least one of oxygen and carbon dioxide in the exhaled breath, may be measured. Therefore, the main body 2 may include only one of the oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 as the “breath gas concentration measuring means”.

The flow sensor 3 functions as a respiratory air volume measuring unit 31 or the like for measuring the flow velocity (flow rate) of the respiratory air of the subject.

The calibrator 4 is a control unit that controls each hardware such as a sensor in the calibrator 4 by executing a program stored in the storage device by the CPU and controlling each hardware provided in the calibrator 4. 41, a carbon dioxide concentration measuring unit 42 that measures the gas concentration of carbon dioxide contained in the calibration gas (atmospheric gas), a calibration gas supply unit 43 that supplies the calibration gas to the main body 2 and the carbon dioxide concentration measuring unit 42, carbon dioxide. It functions as a storage unit 44 that stores measured values of concentration and the like, and a communication unit 45 that communicates (transmits and receives) various data.

The carbon dioxide concentration measuring unit 42 is an example of the "atmospheric gas concentration measuring means" of the present invention. The exhaled gas analyzer 1 according to the present disclosure measures the gas concentration of a predetermined gas which is at least one of oxygen and carbon dioxide in the atmospheric gas, and it is considered that the measured value is originally known and constant. Let it be the true value of the gas concentration in the atmosphere. At this time, since it is possible to measure either oxygen or carbon dioxide in the atmospheric gas and obtain the other by calculation, the breath gas analyzer 1 according to the present embodiment is a "air gas concentration measuring means". However, the present invention is not limited to this, and an oxygen concentration measuring unit may be provided in addition to the carbon dioxide concentration measuring unit 42, or only the oxygen concentration measuring unit may be provided. May be good.

The information processing device 5 is a control unit that controls each hardware in the information processing device 5 by executing a program stored in the storage device by the CPU and controlling each hardware provided in the information processing device 5. 51, an input unit 52 for inputting data, etc., an output unit 53 for outputting processed data, etc., a data processing unit 54 for performing data processing using various measured data, and a true value and a measured value of gas concentration. It functions as a calibration unit 55 for obtaining a relationship (relational expression), a storage unit 56 for storing measured values in the main body 2 and the calibrator 4, and each breath gas analysis data, and a communication unit 57 for communicating (transmitting and receiving) various data. ..

The calibration unit 55 uses the gas concentration of the predetermined gas in the atmospheric gas measured by the atmospheric gas concentration measuring means exemplified by the carbon dioxide concentration measuring unit 42 to calibrate the predetermined gas in the atmospheric gas. By setting the gas concentration to the true value, the gas concentration of the predetermined gas in the exhaled breath is calibrated. Specifically, the calibration unit 55 is a combination of the gas concentration measurement value of the gas measured by the exhaled gas concentration measuring means exemplified by the oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 and the gas concentration true value of the measured gas. By obtaining the relational expression, the gas concentration of the predetermined gas in the exhaled breath is calibrated. In addition, the data processing unit 54 calculates various exhaled gas analysis data using the gas concentration of the predetermined gas in the exhaled breath calibrated based on the above relational expression.

For each of oxygen and carbon dioxide, the relational expression uses the measured values at two points, that is, at the time of measuring atmospheric gas (measurement point A) and at the time of measuring calibration gas (measurement point B), and their true values. It is obtained as a linear function (linear expression) that passes through. In the present embodiment, the number of measurement points is set to two, and a linear expression passing through these two points is obtained, but the present invention is not limited to this. For example, it is assumed that the gas concentrations of the atmospheric gas and the calibration gas are measured multiple times, or that two types of calibration gases having different gas concentrations are used in addition to the atmospheric gas. Therefore, three or more measurement points are used. It may be provided and the correspondence relationship (relational expression) may be obtained by a linear regression equation, curve approximation, or the like.

In the present embodiment, the calibration unit 55 has a gas concentration generally known as a true value of the gas concentration of the atmospheric gas, which is a calibration gas (for example, an oxygen concentration of 20.93% and a carbon dioxide concentration of 0). Instead of using .04%), the value obtained by actually measuring the gas concentration of atmospheric gas by the carbon dioxide concentration measuring unit 42 is used. Therefore, even if the atmospheric gas concentration fluctuates from the above known concentration due to environmental factors such as the number of people in the room, the gas concentration of the atmospheric gas is actually measured, and the measured gas concentration measured value is set as the true value of the gas concentration. Therefore, it is possible to accurately obtain the relational expression between the measured value and the true value of the gas concentration. That is, by calibrating the exhaled gas concentration using the relational expression thus obtained, it is possible to eliminate the error due to the fluctuation of atmospheric carbon dioxide.

<Processing flow>
Next, the flow of processing executed by the exhaled gas analyzer according to the present embodiment will be described with reference to a flowchart. The specific contents and processing order of the processing shown in the flowchart described below are examples for implementing the present disclosure. The specific processing content and processing order may be appropriately selected according to the embodiment of the present disclosure.

FIG. 3 is a flowchart showing an outline of the flow of the gas concentration calibration process according to the present embodiment. The gas concentration calibration process according to the present embodiment is executed when the user inputs data related to an instruction to start the calibration process.

In step S101, the gas concentration which is the true value (actual atmospheric carbon dioxide concentration) of the gas to be measured (carbon dioxide) in the atmospheric gas is measured. The carbon dioxide concentration measuring unit 42 in the calibrator 4 measures the gas concentration (%) of carbon dioxide in the atmospheric gas. In the present embodiment, for example, the carbon dioxide concentration measuring unit 42 acquires a measured value of 0.2% as the carbon dioxide concentration in the atmospheric gas. The measured carbon dioxide concentration in the atmospheric gas can be treated as the _{intake gas carbon dioxide fraction (FICO2) at the time of exhaled gas analysis.} After that, the process proceeds to step S102.

In step S102, the true value of the gas concentration of oxygen in the atmospheric gas (actual atmospheric oxygen concentration) is calculated. The main components of atmospheric gas in the general environment are nitrogen, oxygen, carbon dioxide, and argon, and these gases are responsible for the gas composition of about 99% of the atmospheric gas. That is, the value obtained by adding all the gas concentrations of these gases is about 99%. In the indoor environment, assuming that nitrogen and argon are invariant because there is no source and source of consumption, the value obtained by adding the gas concentrations of oxygen and carbon dioxide is considered to be a constant (A), so the increase in carbon dioxide is oxygen. It can be said that there is a decrease in. From this, when the calibration unit 55 in the information processing apparatus 5 receives the carbon dioxide concentration x (%) in the atmospheric gas measured in step S102, the true oxygen concentration y (%) in the atmospheric gas is calculated by the following formula. Calculated by

Note that A can be arbitrarily set as long as it is a value obtained by adding the atmospheric oxygen concentration and the atmospheric carbon dioxide concentration, and in the present embodiment, 20.97% is adopted. When the constant A is set to 20.97% and the measured value of 0.2% is acquired as the carbon dioxide concentration x in the atmospheric gas in step S101, the calibration unit 55 determines the true value of the oxygen concentration in the atmospheric gas according to the above formula. y is calculated as 20.77%. The calculated oxygen concentration in the atmospheric gas can be _{treated as the intake gas oxygen fraction concentration (FIO2) at the time of exhaled gas analysis.} The process in step S102 may be performed when calculating the relational expression between the true gas concentration value and the measured gas concentration value in step S107. After that, the process proceeds to step S103.

In step S103, the gas concentration of the measurement target gas (oxygen, carbon dioxide) in the atmospheric gas is measured in the main body 2. The oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 in the main body 2 measure the gas concentrations of oxygen and carbon dioxide in the atmospheric gas taken in through the sampling tube or the like by the pump or the like in the main body 2, respectively. In the present embodiment, for example, the oxygen concentration measuring unit 23 acquires the measured value of 1.5 V as the oxygen concentration output value in the atmospheric gas, and the carbon dioxide concentration measuring unit 24 obtains the measured value as the carbon dioxide concentration in the atmospheric gas. Get 0.1%. After that, the process proceeds to step S104.

In step S104, the calibration gas, which is the calibration gas, is supplied to the oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 in the main body 2. When the main body 2 and the calibrator 4 are connected by a sampling tube or the like, the calibration gas supply unit 43 supplies the calibration gas from the calibrator 4 to the oxygen concentration measurement unit 23 and the carbon dioxide concentration measurement unit 24. In this embodiment, a calibration gas having a gas concentration of 15% oxygen concentration and 5% carbon dioxide concentration is adopted. After that, the process proceeds to step S105.

In step S105, the gas concentration of the measurement target gas (oxygen, carbon dioxide) in the calibration gas is measured in the main body 2. The oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 in the main body 2 measure the gas concentrations of oxygen and carbon dioxide in the calibration gas supplied by the calibration gas supply unit 43, respectively. For example, the oxygen concentration measuring unit 23 acquires a measured value of 1.0 V as the oxygen concentration output value in the calibration gas, and the carbon dioxide concentration measuring unit 24 obtains the measured value of 4.5% as the carbon dioxide concentration in the calibration gas. get.

Note that steps S103 and steps S104 to S105 are in no particular order, and the gas concentration of atmospheric gas may be measured in the main body 2 after the calibration gas is supplied to the main body 2 and the gas concentration is measured. After that, the process proceeds to step S106.

Ｘａ：大気ガス（濃度）測定値
Ｙｂ：大気ガス（濃度）真値
Ｘａ’：校正ガス（濃度）測定値
Ｙｂ’：校正ガス（濃度）真値 In step S106, the relationship (relational expression) between the measured gas concentration value related to the gas to be measured (oxygen, carbon dioxide) and the true gas concentration value is obtained. The calibration unit 55 uses the measured values at two points, that is, at the time of measuring atmospheric gas (measurement point A) and at the time of measuring calibration gas (measurement point B), and their true values for each of oxygen and carbon dioxide. Find a linear function (linear expression) that passes through. The relational expression (linear function) between the measured gas concentration value (x) and the true gas concentration value (y) is expressed by the following expression.

Xa: Measured value of atmospheric gas (concentration) Yb: True value of atmospheric gas (concentration) Xa': Measured value of calibration gas (concentration) Yb': True value of calibration gas (concentration)

FIG. 4 is a diagram showing the relationship between the measured value and the true value of the carbon dioxide concentration according to the present embodiment. In FIG. 4, the horizontal axis (x) is the measured value (%) of the carbon dioxide concentration, and the vertical axis (y) is the true value (%) of the carbon dioxide concentration. As long as the relationship can be shown, the present invention is not limited to this, and the items indicated by the x-axis and the y-axis may be reversed. Further, the measured value of the carbon dioxide concentration is not limited to the gas concentration (%), and may be an output voltage (V) or the like corresponding to the gas concentration, and the output voltage corresponding to the gas concentration as the carbon dioxide concentration measured value. The relational expression between (V) and the true value (%) of carbon dioxide concentration may be obtained.

As shown in FIG. 4, at the time of measuring the atmospheric gas (measurement point A), the true value (Yb) of the carbon dioxide concentration is 0.2% measured in step S101 as the actual atmospheric carbon dioxide concentration, which is carbon dioxide. The measured value of carbon concentration (Xa) is 0.1% measured in step S103. Further, at the time of measuring the calibration gas (measurement point B), the true value (Yb') of the carbon dioxide concentration is 5.0%, which is the known carbon dioxide concentration of the calibration gas, and the measured value of the carbon dioxide concentration (Xa'). ) Is 4.5% measured in step S105. The calibration unit 55 obtains a linear function passing through two points, measurement point A and measurement point B, by using these measured values and true values and the above relational expression.

FIG. 5 is a diagram showing the relationship between the measured value and the true value of the oxygen concentration according to the present embodiment. In FIG. 5, the horizontal axis (x) is the measured value (output voltage) (V) of the oxygen concentration, and the vertical axis (y) is the true value (%) of the oxygen concentration. The item is not limited to this as long as it can show the relationship with, and the items indicated by the x-axis and the y-axis may be reversed. Further, the measured value of the oxygen concentration is not limited to the output voltage (V), and may be a gas concentration (%) or the like. The relational expression of may be obtained.

As shown in FIG. 5, at the time of measuring the atmospheric gas (measurement point A), the true value (Yb) of the oxygen concentration is 20.77% calculated in step S101 as the actual atmospheric oxygen concentration, which is the oxygen concentration. The measured value (Xa) is 1.5 V measured in step S103. Further, at the time of measuring the calibration gas (measurement point B), the true value (Yb') of the oxygen concentration is 15.0%, which is the known oxygen concentration of the calibration gas, and the measured value of the oxygen concentration (Xa') is. It is 1.0V measured in step S105. The calibration unit 55 obtains a linear function passing through two points, measurement point A and measurement point B, by using these measured values and true values and the above relational expression. After that, the process proceeds to step S107.

In step S107, the gas concentration of the measurement target gas (oxygen, carbon dioxide) in the exhaled gas of the subject is measured in the main body 2. The oxygen concentration measuring unit 23 and the carbon dioxide concentration measuring unit 24 in the main body 2 respectively, when the exhaled breath of the subject collected by the respiratory air collecting unit such as the respiratory air mask connected to the flow sensor 3 is introduced into the main body 2. The gas concentration of the measurement target gas in the exhaled breath is measured. Further, in step S107, the flow velocity (flow rate) of the respiratory air of the subject may be measured by the respiratory air volume measuring unit 31 and converted into an electric signal by the A / D conversion unit 22. After that, the process proceeds to step S108.

In step S108, the true value of the exhaled gas concentration between the two measurement points (A and B) is obtained by applying the measured value of the exhaled gas concentration to the relational expression between the true value of the gas concentration and the measured value. The calibration unit 55 applies the measured values (concentration value or output voltage) of the oxygen concentration and the carbon dioxide concentration in the exhaled gas measured in step S107 to x of the relational expression obtained in step S106, respectively. The true value (y) of the oxygen concentration and the carbon dioxide concentration in the exhaled gas is calculated. The oxygen concentration true value and the carbon dioxide concentration true value of expiratory gas this is calculated, respectively, exhaled gas oxygen fraction concentration of exhalation gas analysis (F _EO2) and exhaled gas carbon dioxide fraction concentration (F _ECO2 ) Can be handled. After that, the process proceeds to step S109.

In step S109, various breath gas analysis data are calculated. The data processing unit 55 uses the true oxygen concentration value and the true carbon dioxide concentration value in the exhaled breath calculated in step S108 to measure the minute oxygen intake, the minute carbon dioxide excretion, the oxygen intake / body weight, and the oxygen ventilation. Calculate breath gas analysis data such as equivalent and carbon dioxide ventilation equivalent. After that, the process shown in this flowchart ends.

In the present embodiment, as an example of the case where the carbon dioxide in the atmospheric gas rises due to environmental factors or the like, the carbon dioxide concentration measuring unit 42 measures the carbon dioxide concentration in the atmospheric gas to be 0.2%, and the gas concentration value. Was explained as the case where the true value of the carbon dioxide concentration in the atmospheric gas is used. Here, FIG. 6 is a diagram showing the relationship between the conventional measured value of carbon dioxide concentration and the true value (without considering the fluctuation of the atmospheric gas concentration). As shown in FIG. 6, in the conventional calibration method that does not consider the fluctuation of the atmospheric gas concentration, carbon dioxide is produced at the time of atmospheric gas measurement (measurement point A) even when carbon dioxide is increased due to environmental factors or the like. The relational expression is calculated assuming that the true value of the concentration is 0.04%, which is generally a known concentration. Therefore, it can be seen that the relational expression (FIG. 4) in consideration of the increase in carbon dioxide concentration due to environmental factors and the like in the present embodiment is a more accurate relational expression as compared with the relational expression shown in FIG.

By the method described above, it is possible to obtain the relationship (formula) between the measured value of the gas concentration in the main body 2 (oxygen concentration measuring unit 23, carbon dioxide concentration measuring unit 24) and the true value of the gas concentration. Further, in the present embodiment, since the gas concentration measurement value of the atmospheric gas by the carbon dioxide concentration measuring unit 42 is used as the gas concentration true value of the atmospheric gas, even when the gas concentration of the atmosphere is not constant due to environmental factors. , It is possible to accurately obtain the relational expression between the measured value and the true value of the gas concentration. Further, since the relational expression can be obtained accurately, the true value of the gas concentration in the exhaled gas can be calculated accurately by calculating the true value of the gas concentration in the exhaled gas using the relational expression. This makes it possible to accurately obtain breath gas analysis data, which is a parameter that uses the true value of the gas concentration.

1 Breath gas analyzer 2 Main unit 3 Flow sensor 4 Calibrator 5 Information processing device

Claims (8)

Comprising a first carbon dioxide concentration measuring means for measuring the gas concentration of carbon dioxide in exhaled breath, and expired gas concentration measurement means for measuring the gas concentration in the expiration,
A second carbon dioxide concentration measuring means for measuring the gas concentration of carbon dioxide in the atmosphere gas, and atmospheric gas concentration measuring means for measuring the gas concentration in the atmosphere gas,
Using atmospheric gas and a calibration gas having a known gas concentration, a relational expression between the gas concentration measured value by the first carbon dioxide concentration measuring means of the exhaled gas concentration measuring means and the true gas concentration value is calculated, and the relational expression is calculated. Based on the formula, a calibration means for calibrating the gas concentration of carbon dioxide in the exhaled breath measured by the first carbon dioxide concentration measuring means, and a calibration means.
With
It said calibration means, the relational expression as the second gas concentration of carbon dioxide of atmospheric gas measured by the carbon dioxide concentration measuring means, gas concentration true value of the carbon dioxide in the atmosphere gas in the atmosphere gas concentration measuring means To calculate,
Breath gas analyzer. The first carbon dioxide concentration measuring means measures the gas concentration of carbon dioxide contained in the atmospheric gas and the calibration gas, respectively.
The calibration means calculates the relational expression based on the measurement point of the atmospheric gas and the measured value of the gas concentration of carbon dioxide and the true value of the gas concentration at the measurement point of the calibration gas.
The exhaled gas analyzer according to claim 1. The relational expression is a linear function passing through two points, the measurement point of the atmospheric gas and the measurement point of the calibration gas.
The exhaled gas analyzer according to claim 2. The calibration means obtains the true value of the gas concentration of carbon dioxide in the exhaled breath by applying the measured value of the gas concentration of carbon dioxide in the exhaled breath measured by the first carbon dioxide concentration measuring means to the above relational expression. By determining, the measured gas concentration of carbon dioxide in the exhaled breath is calibrated.
The exhaled gas analyzer according to any one of claims 1 to 3. The gas concentration measurement accuracy of the second carbon dioxide concentration measuring means is higher than the gas concentration measuring accuracy of the first carbon dioxide concentration measuring means.
The breath gas analyzer according to any one of claims 1 to 4. The exhaled gas concentration measuring means further includes an oxygen concentration measuring means for measuring the gas concentration of oxygen in the exhaled breath.
The calibration means,
Using the atmospheric gas and the calibration gas, the relational expression between the gas concentration measurement value by the oxygen concentration measuring means of the exhaled gas concentration measuring means and the true gas concentration value is calculated, and the oxygen concentration measuring means is based on the relational expression. Further calibrates the gas concentration of oxygen in the exhaled breath measured by
The gas concentration true value of the oxygen in the atmosphere gas, a predetermined constant indicating the concentration obtained by adding the oxygen concentration and carbon dioxide concentration in the atmosphere gas, the atmospheric gas measured by the second carbon dioxide concentration measuring means Calculated by subtracting the gas concentration of carbon dioxide, and calculate the relational expression related to oxygen.
The breath gas analyzer according to any one of claims 1 to 5. In the breath, the expired gas concentration measurement means for measuring the gas concentration of the first predetermined gas is at least one of oxygen and carbon dioxide,
Atmospheric gas, and atmospheric gas concentration measuring means for measuring the gas concentration of the second predetermined gas is at least one of oxygen and carbon dioxide,
A calibration means for calibrating the gas concentration of the first predetermined gas in the exhaled breath measured by the exhaled gas concentration measuring means using an atmospheric gas and a calibration gas having a known gas concentration, and a calibration means.
With
The exhaled gas concentration measuring means measures the gas concentration of the first predetermined gas for each of the atmospheric gas and the calibration gas, and measures the gas concentration.
The calibration means is
The true value of the gas concentration of the first predetermined gas in the atmospheric gas is determined based on the gas concentration of the second predetermined gas in the atmospheric gas measured by the atmospheric gas concentration measuring means.
For common gas, the gas concentration measurement value in the atmospheric gas and the calibration gas measured by the breath gas concentration measuring means, the gas concentration true value of the atmospheric gas, and the gas concentration true value in the known calibration gas. To calculate the relational expression between the measured gas concentration value measured by the exhaled gas concentration measuring means and the true value of the gas concentration, and based on the relational expression, the first predetermined gas in the exhaled breath measured. Calibrate the gas concentration,
Breath gas analyzer. The first carbon dioxide concentration measuring means, and the secondary exhaled carbon dioxide concentration measurement step of measuring the gas concentration of the oxidation-carbon exhaled,
The first carbon dioxide concentration measuring means includes a first step of measuring the carbon dioxide concentration in the atmospheric gas, which measures the gas concentration of carbon dioxide in the atmospheric gas.
The first carbon dioxide concentration measuring means includes a step of measuring the carbon dioxide concentration in the calibration gas for measuring the gas concentration of carbon dioxide in the calibration gas having a known gas concentration, and a step of measuring the carbon dioxide concentration in the calibration gas.
A second carbon dioxide concentration measuring means, and the secondary second atmosphere gas carbon dioxide concentration measuring step of measuring the gas concentration of the oxidation-carbon in the atmosphere gas,
The gas concentration of carbon dioxide in the atmospheric gas measured by the step of measuring the carbon dioxide concentration in the second atmospheric gas is determined as the true value of the gas concentration of carbon dioxide in the atmospheric gas, and the carbon dioxide concentration in the first atmospheric gas is determined. The measured value of carbon dioxide concentration in the atmospheric gas measured by the measurement step, the measured value of carbon dioxide concentration in the calibration gas measured by the step of measuring the carbon dioxide concentration in the calibration gas, and the measured value of the carbon dioxide concentration in the atmospheric gas. Using the true value of the gas concentration of carbon dioxide and the true value of the gas concentration of carbon dioxide in a known calibration gas, the measured value of the gas concentration and the true value of the gas concentration measured by the first carbon dioxide concentration measuring means And a calibration step of calibrating the gas concentration of carbon dioxide in exhaled carbon dioxide measured by the step of measuring carbon dioxide concentration in exhaled breath based on the relational expression of
Breath gas analysis method consisting of.

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