JPH07100127A - Oxygen saturation recording apparatus - Google Patents

Abstract

PURPOSE:To provide an oxygen saturation recording apparatus which enables a doctor to properly take care of a patient with respiratory failure by way of storing the detected rate of absorbance and the detected data of an organic behavior as time series data for a certain period and making use of the data to be observed by a doctor. CONSTITUTION:A probe of an absorbance detector 1 is placed at the part to be examined of a patient with respiratory failure. When the measurement interval is set, a control unit 9 starts measuring the patient's oxygen saturation degree of the artery and detecting the patient's behavior according to the measurement interval. After extracting the absorbance components from the arterial blood based on the absorbance detected in the probe, CPU of the control unit 9 calculates the artery oxygen saturation degrees as well as seeks the number of heartbeats, and further incorporates the detected data along with the absorbance through a behavior detection device 2 and store them as time series data in a memory 4. When recording of each detected datum for a certain period is completed, CPU of the control unit 9 writes time series data on a recording card 10 so that the card is utilized for the management in taking care of the patient.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxygen saturation measuring and recording apparatus for measuring and recording arterial blood oxygen saturation based on a detected value of absorbance at a predetermined site of a living body (eg, respiratory failure patient).

[0002]

2. Description of the Related Art Today, with the progress of an aging society, the number of patients suffering from chronic illness and requiring continuous medical treatment, such as respiratory failure, is increasing. Since such patients with respiratory failure are difficult to treat by going to the hospital, home oxygen therapy is performed. This home oxygen therapy is to increase oxygen concentration in inhaled air to maintain arterial blood oxygen saturation, thereby ensuring oxygen transport to various organs and peripheral tissues of the body and prolonging survival time. This is a treatment method in which oxygen is supplied from a generator to the respiratory tract of a patient.

By the way, the oxygen saturation of arterial blood decreases depending on the amount of exercise. Therefore, for patients with respiratory failure, the arterial oxygen saturation is restricted so that it does not decrease from a certain value, or the amount of exercise is prescribed as exercise therapy in order to prevent further deterioration of the medical condition. for,
It is necessary to understand athletic ability.

For this reason, arterial blood oxygen saturation has been measured by a device for measuring and measuring oxygen saturation (also referred to as a pulse oximeter) for patients with respiratory failure who are undergoing home oxygen therapy. The result is used as a judgment material for managing the patient.

[0005]

However, since the conventional oxygen saturation measuring and recording apparatus cannot simultaneously measure the behavior of the patient closely related to the arterial oxygen saturation, it is not suitable for the management of the respiratory failure patient. Was enough.

Therefore, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide an oxygen saturation measuring and recording apparatus capable of appropriately managing a patient with respiratory failure.

[0007]

In order to achieve the above object, an oxygen saturation measuring and recording apparatus according to claim 1 measures and records the arterial oxygen saturation based on the detected value of the absorbance at a specific part of the living body. In an oxygen saturation measurement recording device, a behavior detection unit that detects the behavior of the living body, a storage unit that can store each detected value as time series data for a predetermined period, and a display that displays the time series data of each detected value. And a battery for supplying power to each part of the device.

Further, in the oxygen saturation measuring and recording apparatus according to the present invention, the action detecting means is provided with an electrocardiographic detecting section for detecting heartbeat information from a living body.

Further, in the oxygen saturation measuring and recording apparatus according to a third aspect of the present invention, the action detecting means is provided with an acceleration detecting section for detecting the number of steps of the living body.

Further, in the oxygen saturation measuring and recording apparatus according to the present invention, the action detecting means is provided with an angle detecting section for detecting the posture of the living body.

[0011]

According to the oxygen saturation measuring and recording apparatus of the first aspect, the detected value of the absorbance and the detected value of the behavior of the living body are stored as time series data in the storage means for a predetermined period. By observing this data by the doctor, the limit of the behavior of the respiratory failure patient can be known, so that appropriate management of the patient can be performed. Further, the time-series data of each detected value is displayed on the display means, and the respiratory failure patient can perform self-management. In addition, since the device is portable by being driven by a battery, various types of detection are facilitated.

According to the oxygen saturation measuring / recording device of the second aspect, the relationship between the burden on the heart and the oxygen saturation of arterial blood is clarified by detecting the heartbeat information of the living body by the electrocardiographic detection unit.

According to the oxygen saturation measuring and recording apparatus of the third aspect, the relationship between the step count and the arterial blood oxygen saturation is clarified by detecting the number of steps of the living body by the acceleration detecting section.

According to the oxygen saturation measuring / recording apparatus of the fourth aspect, the relationship between the posture and the arterial oxygen saturation is clarified by detecting the posture of the living body by the angle detecting section.

[0015]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a schematic configuration diagram showing an embodiment of an oxygen saturation measuring and recording apparatus of the present invention.

This apparatus is attached to a specific part such as a finger or an ear of a living body (mainly a patient with respiratory failure) to detect the absorbance at the part, and an action detecting means 2 to detect the action of the patient. A clock / calendar 3, a memory 4 for storing time series data, a display section 5 such as an LCD (liquid crystal display), and an operation section 6 including various keys,
A communication interface 7 capable of communicating with a host computer (not shown), an attached interface 8 capable of writing / reading data to / from a recording card 10 described later, and a card insertion not shown for inserting a recording card 10 described later. Mouth, battery (not shown) for supplying power to each part of the device, and control part 9 for controlling each part of this device
And has a general configuration.

Next, the details of each of the above parts will be described.

The absorbance detector 1 comprises a probe (not shown), and a light emitting diode which emits red light (wavelength 660 nm) and infrared light (wavelength 940 nm) in the probe,
And a photodiode for receiving the red light and the infrared light emitted by the light emitting diode. The light from the light emitting diode is transmitted to a specific part of the patient who wears the probe, and the absorbance (transmitted light amount) of the light is detected by the photodiode and converted into an electric signal, which is input to the control unit 9.

The behavior detecting means 2 includes a breathing frequency detecting section 2
0, an acceleration detector 21, and a posture detector 22 are provided, and the detection values of the detectors 20 to 22 are input to the controller 9.

As the acceleration detecting section 21, for example, a pedometer capable of detecting the number of steps of the patient is applied.

For the posture detection unit 22, for example, an angle sensor arranged so as to correspond to the directions in which the detection directions are orthogonal to each other is applied, and the posture of the patient such as lying down, lying down, standing, etc. can be detected. ing. By using such an angle sensor, the acceleration detector 21 may also detect the number of steps.

The breathing frequency detecting unit 20 is provided on the chest or abdomen of a patient whose circumference changes with breathing, as disclosed by the applicant in Japanese Patent Application No. 4-275849, entitled "Respiratory Signal Extraction Device". Wear a belt with elasticity in the direction,
The respiratory signal is taken out from the patient based on the belt expansion / contraction information. As the elastic belt, for example, an optical transmission member that expands and contracts in the longitudinal direction to change the amount of transmitted light, or an elastic conductive member that expands and contracts in the longitudinal direction to change electric resistance are used. Also, the breathing frequency detection unit 2
As for 0, in addition to the above method, a piezoelectric sensor, a thermistor, or the like may be attached to the nose to take out a respiratory signal.

The operation section 6 can set a measurement interval, but can select both manual setting and automatic setting. In the manual setting, for example, 1 second, 5 seconds, 10 seconds, 30 seconds, 1 minute, 5 minutes can be set, and in the automatic setting, a fixed time (for example, 1
Minute) is automatically set. Further, in the automatic setting, the control unit 9 determines whether the patient is awake or sleeping based on the detection value from the posture detection unit 22, and when it is awake, sets the measurement interval to 1 minute, When sleeping, it may be set to 5 minutes. This allows battery savings.

The communication interface 7 is RS23.
It is of the 2C type, and the contents stored in the memory 4 can be directly transferred to a host computer (not shown) via the interface 7.

The control unit 9 has a CPU, an internal memory and the like, and takes in the detected value of the absorbance from the probe of the absorbance detection unit 1 to calculate the oxygen saturation of arterial blood of the patient and the detected value of the absorbance. The heart rate is calculated based on the above, and each detected value from the action detecting means 2 detected at the same time as the absorbance is taken in, and the memory 4 as time series data together with the time measurement information (measurement date and time) from the clock / calendar 3.
Is something to remember. Further, the control unit 9 is adapted to scroll-display the time-series data stored in the memory 4 on the display unit 5 based on the depression of a scroll switch (not shown) of the operation unit 6. Further, the control unit 9 can write the time-series data stored in the memory 4 into the recording card 10 inserted from an insertion opening (not shown) via the attached interface 8.

Next, the calculation of the arterial blood oxygen saturation by the CPU will be described with reference to FIGS. FIG. 2 is a diagram showing the principle of extraction of light-absorbing components of arterial blood, and FIG.
It is a relationship diagram between ₂ and R / IR ratio. As shown in FIG. 2, the absorbance detected by the probe of the absorbance detecting unit 1 includes a light absorbing component due to arterial blood, a light absorbing component due to venous blood, and a light absorbing component due to tissue. Since the fluctuation component of the absorption is due to arterial blood, the CPU numerically subtracts the fluctuation-invariant components (the absorption component due to venous blood and the absorption component due to tissue) from the overall absorbance to extract only the absorbance from the arterial blood. I am trying to do it. Next, the CPU performs this extraction for red light and infrared light, and the ratio (R / IR ratio) of the absorbance (R) of red light and the absorbance (IR) of infrared light.
Then, the saturation degree SaO ₂ is calculated from the relational information between the arterial oxygen saturation degree SaO ₂ and the R / IR ratio stored in the internal memory as shown in FIG. Here, "oxygen saturation" means the ratio between the amount of oxygen actually bound to hemoglobin and the maximum amount of oxygen that can be bound, and the oxygen saturation of arterial blood is 97 to 98% when a healthy person is quiet. It will be about. Further, as the amount of exercise increases, the bond between hemoglobin and oxygen weakens, and the oxygen saturation of arterial blood tends to decrease. Therefore, by measuring the arterial blood oxygen saturation and detecting the behavior of the patient, the limit of the behavior of the patient can be known, so that appropriate management can be performed for the patient with respiratory failure.

Next, the operation of the embodiment having the above configuration will be described.

First, a patient with respiratory failure attaches the probe of the absorbance detecting unit 1 to a specific site such as his / her finger or ear.

Next, the patient operates the operation unit 6 to turn on the power of the apparatus and set the measurement interval. The control unit 9 starts measuring the arterial oxygen saturation of the patient himself and detecting the behavior of the patient himself at the set measurement interval.

The CPU of the control unit 9 receives the detection signal from the probe of the absorbance detection unit 1, extracts the absorption component of arterial blood from the absorbance detected by the probe, and then extracts the arterial oxygen saturation level stored in the internal memory. The arterial blood oxygen saturation level SaO ₂ is calculated from the relationship information between SaO ₂ and the R / IR ratio, the heart rate is calculated based on the detected absorbance value, and the detection by the action detecting means 2 is performed simultaneously with the absorbance value. The detection values from the units 20 to 22 are fetched and stored in the memory 4 as time-series data together with the time measurement information (measurement date and time) from the clock / calendar 3. Here, when the patient presses the scroll switch of the operation unit 6, the time-series data stored in the memory 4 is scroll-displayed on the display unit 5.

When the recording of each detected value (measured value) is completed for a certain period of time, for example, for one week, the patient inserts the recording card 10 from an insertion opening (not shown). The CPU of the control unit 9
The time-series data stored in the memory 4 is written to the inserted recording card 10 via the attached interface 8. When the recording card 10 is taken to a hospital, the time-series data is read from the recording card 10 and used as a judgment material for managing the patient. When a communication line is provided with a host computer installed in a hospital or the like, the time series data stored in the memory 4 may be transferred to the host computer via the communication interface 7. .

According to the present embodiment as described above, the detected value of the absorbance and the detected value of the behavior of the patient are stored as time series data in the memory 4 for a predetermined period, so that the doctor observes the time series data. As a result, the limit of the behavior of the respiratory failure patient can be known, and appropriate management of the patient can be performed. For example, after walking for 10 minutes, it is better to take a rest of 5 minutes. Moreover, since the time-series data of each detected value can be displayed on the display unit 5, the respiratory failure patient can perform self-management. In addition, since the device is portable by being driven by a battery, various types of detection are facilitated.

The present invention can be variously modified within the scope of the gist other than the above-mentioned embodiment. For example, instead of the display unit 5, the printer may output the time series data. Further, as the action detecting means 2, other than the ones mentioned in the present embodiment, an action detecting means 2 may be connected as required.
Further, in the present embodiment, the heart rate is calculated by the control unit 9 based on the detected value of the absorbance, but an electrocardiographic detection unit for detecting the heart rate may be provided. In addition, a modem (Mo
dem) may be used. This allows
Time series data is transmitted from the patient side by personal computer communication,
The doctor's diagnosis and management will be quick and easy.

[0035]

According to the present invention described in detail above, the following effects can be obtained.

According to the first aspect of the present invention, the detected value of the absorbance and the detected value of the action of the living body are stored as time series data in the storage means for a predetermined period, so that the doctor observes the time series data. As a result, the limit of the behavior of the respiratory failure patient can be known, and appropriate management of the patient can be performed. Further, since the time-series data of each detected value can be displayed on the display means, the respiratory failure patient can also perform self-management. In addition, since the device can be carried by a battery, it can be easily detected.

According to the second aspect of the present invention, the heartbeat information of the living body is detected by the electrocardiographic detection unit, so that the relationship between the burden on the heart and the oxygen saturation level becomes clear, which is suitable for patients with respiratory failure. Can be managed.

According to the third aspect of the present invention, by measuring the number of steps of the living body by the acceleration detecting section, the relationship between the number of steps and the oxygen saturation level is clarified, and it becomes possible to appropriately manage the patient with respiratory failure. Become.

According to the invention described in claim 4, by measuring the posture of the living body by the angle detecting portion, the relationship between the posture and oxygen saturation is clarified, and appropriate management for a respiratory failure patient is possible. Become.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of an oxygen saturation measurement recording device of the present invention.

FIG. 2 is a diagram for explaining the operation of the CPU of the control unit of this embodiment.

FIG. 3 is a relational diagram stored in an internal memory of a control unit according to the present embodiment.

[Explanation of symbols]

 1 Absorbance Detection Section 2 Behavior Detection Section 20 Breathing Frequency Detection Section 21 Acceleration Detection Section 22 Posture Detection Section 4 Memory (Storage Section) 5 Display Section (Display Section) 9 Control Section

Claims (4)

[Claims] 1. An oxygen saturation measuring and recording device for measuring and recording arterial oxygen saturation based on a detected value of absorbance at a specific part of a living body, comprising: a behavior detecting means for detecting a behavior of the living body; Is stored as time-series data for a predetermined period, display means for displaying time-series data of each of the detected values, and a battery for supplying power to each part of the device, and oxygen saturation. Measurement recording device. 2. The oxygen saturation measuring and recording apparatus according to claim 1, wherein the action detecting means comprises an electrocardiographic detecting section for detecting heartbeat information from a living body. 3. The action detecting means comprises an acceleration detecting section for detecting the number of steps of a living body.
The oxygen saturation measurement recording device described. 4. The oxygen saturation measuring and recording apparatus according to claim 1, wherein the action detecting means comprises an angle detecting section for detecting a posture of a living body.