JP6675228B2 - Life activity display device, life activity display method, and walking test system - Google Patents

Description

  The present invention relates to a life activity display device, a life activity display method, and a walking test system used for a walking test for confirming the effect of respiratory rehabilitation, for example.

  Tests for confirming the effects of respiratory rehabilitation include a walking test within time and a shuttle walking test.

In the walking test in time, the subject is allowed to walk reciprocatingly for a predetermined time, for example, at a distance of 30 m, and at this time, the walking distance, borg scale (maximum dyspnea or subjective exercise intensity of the subject). Indices of breathlessness and lower limb fatigue), SpO ₂ (arterial oxygen saturation), and pulse rate are measured.

In the shuttle walking test, a subject is caused to reciprocate between cones placed at both ends of a 10 m course, for example. The subject walks in time with the dial tone output from the speaker. The interval between the sounds is shortened every minute so that the walking speed increases, for example, by 10 m / min. At this time, the walking distance, Borg scale, SpO ₂ , and pulse are measured. The shuttle walking test is stopped when the subject is unable to keep up with the pace or when clinical symptoms such as dyspnea develop. The interval between the cones, the amount of change in the walking speed, and the change interval are not limited thereto, and may be changed as appropriate.

A pulse oximeter is used for such a test for confirming the effect of respiratory rehabilitation. The pulse oximeter is attached to a predetermined living body part of a subject, outputs light toward the living body part, and measures a change in the amount of light transmitted or reflected by the living body part as a pulse signal, thereby obtaining SpO _2. Ask for. In addition, a pulse oximeter is generally designed to measure a pulse in addition to SpO ₂ (for example, see Patent Document 1).

JP 2007-289462 A

Minoru Kanazawa, Ichiro Kuwahira, and 20 others, "Q & A Pulse Oximeter Handbook", 6 pages, [online], April 2014, Japanese Respiratory Society, [Search February 26, 2016], Internet <URL : Https://www.jrs.or.jp/uploads/uploads/files/guidelines/pulse-oximeter_medical.pdf>

Incidentally, in the conventional walk test, the number of steps and a walking distance, walking speed, and Borg scale, and SpO ₂ and pulse rate, and displays and records in chronological associate.

However, it cannot be said that the exercise performed by the patient and the display and the record in which the SpO ₂ and the pulse are sufficiently considered are performed. As a result, it is impossible to accurately grasp the relationship between the exercise and the SpO ₂ and the pulse. It was difficult.

The present invention has been made in view of the above points, and provides a life activity display device, a life activity display method, and a walking test system capable of accurately grasping the relationship between exercise, SpO _2, and pulse rate. I do.

One embodiment of the life activity display device of the present invention,
An SpO ₂ acquiring unit for acquiring SpO ₂ of the subject;
An exercise intensity acquisition unit that acquires the exercise intensity of the subject,
A display unit that displays the SpO ₂ together with a maximum exercise intensity in a period from a first time point, which is a measurement time point of the SpO _2, to a _second time point earlier than the first time point,
Equipped with,
The period from the first time point to the second time point is a time period during which the influence of exercise can appear on SpO ₂ .

One embodiment of the life activity display method of the present invention,
Calculating a maximum exercise intensity during a period from a first time point, which is a measurement time point of SpO2, to a _second time point earlier than the first time point,
The numerical value of the SpO ₂ at the time of the measurement and the numerical value of the maximum exercise intensity within the period are displayed on the same screen,
The period from the first time point to the second time point is a time period during which the influence of exercise can appear on SpO ₂ .

One embodiment of the walking test system of the present invention is:
A pulse oximeter for measuring SpO ₂ of the subject;
The measured SpO ₂ and the exercise intensity of the exercise performed by the subject are input, and the SpO ₂ is converted from a first point in time at which the SpO ₂ is measured to a point in time earlier than the first point in time. A terminal for displaying together with the maximum exercise intensity within the period up to the point
Equipped with,
The period from the first time point to the second time point is a time period during which the influence of exercise can appear on SpO ₂ .

According to the present invention, it is possible to accurately grasp the relationship between the motion and the SpO ₂ and pulse rate.

FIG. 1 is a schematic diagram showing the overall configuration of a walking test system to which the life activity display device of the present invention is applied Block diagram showing main components of pulse oximeter Block diagram showing the main configuration of a tablet terminal FIG. 4A is a diagram for explaining the principle of displaying a measurement result according to the embodiment; FIG. 4A is a diagram showing a change in SpO ₂ ; FIG. 4B is a diagram showing a change in exercise intensity (METs); 4C is a diagram showing a display example according to the embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Structure>
FIG. 1 is a schematic diagram showing the entire configuration of a walking test system to which the life activity display device of the present invention is applied.

  The walking test system 1 includes a pulse oximeter 100 and a tablet terminal 200. The pulse oximeter 100 and the tablet terminal 200 have a function capable of wireless communication with each other. In the case of the present embodiment, the pulse oximeter 100 and the tablet terminal 200 are capable of short-range communication conforming to the Bluetooth (registered trademark) standard. The pulse oximeter 100 transmits the measurement data to the tablet terminal 200 wirelessly. The tablet terminal 200 collects the measurement data received from the pulse oximeter 100, displays the measurement result, and creates a walking test report.

  The pulse oximeter 100 has a main body 110 and a probe 120. The main body 110 and the probe 120 are connected via a cable 130. The main body 110 can be worn near the wrist of the subject using a belt (not shown), and the probe 120 can be worn on the finger of the subject.

  FIG. 2 is a block diagram illustrating a main configuration of the pulse oximeter 100. The probe unit 120 of the pulse oximeter 100 is provided with a light emitting unit 121 and a light receiving unit 122. The light emitting unit 121 includes a first light emitting diode that emits red light (for example, a wavelength of 660 [nm]) having high sensitivity to a change in arterial blood oxygen saturation, and an infrared light (for example, an infrared light that is less affected by arterial oxygen saturation) A second light emitting diode that emits light at a wavelength of 940 [nm]. The light receiving unit 122 is configured by a photodiode, and detects light of the light emitting unit 121 transmitted through the finger. Note that the light receiving unit 122 may be arranged on the reflection path of light from the finger instead of the transmission path of light from the finger, and the light reception unit 122 may detect reflected light from the finger.

The main body 110 obtains the SpO ₂ and the pulse of the subject based on the detection light obtained by the probe 120. This will be specifically described. The light emitting circuit 111 causes the first light emitting diode and the second light emitting diode of the light emitting unit 121 to emit light alternately at predetermined intervals. The transmitted light or reflected light from the finger at that time is detected by the light receiving unit 122, photoelectrically converted, and input to the light receiving circuit 112. The light receiving circuit 112 converts a current signal input from the light receiving unit 122 of the probe unit 120 into a voltage signal. The light receiving circuit 112 separates the converted voltage signal into components corresponding to the wavelengths of the red light and the infrared light, and demodulates two observation signals. In addition, the light receiving circuit 112 performs processing such as amplification and analog-to-digital conversion on the demodulated observation signal, and outputs the processed observation signal to the CPU 113.

The CPU 113 calculates SpO ₂ and the pulse from the observation signal by executing a predetermined program. This calculation method is a known technique as described in, for example, Japanese Patent Application Laid-Open No. H11-157, and thus the description thereof is omitted here. Further, the CPU 113 controls each unit of the pulse oximeter 100. Specifically, the CPU 113 performs various settings based on an operation signal input from the operation unit 117. Further, the CPU 113 performs operation control of the light emitting circuit 111, display control of the display unit 115, communication control of the communication unit 116, and the like.

  In addition to this configuration, an acceleration sensor 118 is provided on the main body 110 of the pulse oximeter 100. The CPU 113 calculates the number of steps of the subject based on the output of the acceleration sensor 118.

The pulse oximeter 100 transmits the measured SpO ₂ , pulse, and step count to the tablet terminal 200 by the communication unit 116 in real time.

As shown in FIG. 3, the tablet terminal 200 includes a display unit 210 including a liquid crystal display with a touch panel, and includes a communication unit 211 that wirelessly receives measurement data transmitted from the pulse oximeter 100. The communication unit 211, SpO ₂ acquisition unit that acquires SpO ₂ of the subject, and has a function as a pulse acquisition unit for acquiring the pulse of the subject. The tablet terminal 200 inputs the number of steps from the information received from the pulse oximeter 100 to the walking speed calculation unit 212.

The walking speed calculator 212 calculates the walking speed of the subject from the input number of steps and the step length. Specifically, the walking speed calculation section 212 calculates the walking speed by the following equation.
Walking speed [m / min] = step length [m] × pitch [step / min] (1)

Here, the storage unit 214 stores the height and age of the subject together with the name of the subject in advance by the user, and the walking speed calculation unit 212 calculates the subject based on the height and age of the subject. Is obtained by estimation, and the walking speed of the subject is calculated by executing the equation (1) using the step length. The stride is obtained, for example, by the following equation.
Step length = height x 0.37 ... (2)
Note that the stride may be determined using an equation other than the equation (2). In addition, the stride may be corrected according to the age, considering that the stride tends to become shorter as the person gets older.

The exercise intensity calculation unit 213 calculates the exercise intensity using the walking speed obtained by the walking speed calculation unit 212. In the case of the present embodiment, the exercise intensity calculator 213 calculates exercise intensity (METs (Metabolic Equivalents)) by the following equation. Incidentally, Expression (3) is a METs calculation expression proposed by the American College of Sports Medicine.
METs = (3.5 + walking speed × coefficient according to walking speed) ÷ 3.5 (3)

  It should be noted that the present invention is not limited to the formula for determining the exercise intensity, and the exercise intensity calculation unit 213 may calculate the exercise intensity using an expression other than the expression (3).

  The CPU 215 displays a measurement result on the display unit 210 and creates a report according to an application program for performing a walking test stored in the storage unit 214.

  In the present embodiment, the number of steps is obtained by the acceleration sensor 118 of the pulse oximeter 100. However, for example, the tablet terminal 200 is provided with a mode for inputting the number of steps visually counted by a medical worker. May be obtained.

<Display of measurement results>
Next, the display of the measurement result according to the present embodiment will be described.

  In the case of the present embodiment, the display of the measurement results of the walking test and the creation of the walking test report are performed by the tablet terminal 200. That is, the tablet terminal 200 receives the measurement data from the pulse oximeter 100, displays the measurement result on the display unit 210, and creates a report according to the application software for performing the walking test.

FIG. 4 is a diagram for explaining the principle of displaying a measurement result according to the present embodiment. FIG. 4A shows a change in SpO ₂ , FIG. 4B shows a change in exercise intensity (METs), and FIG. 4C shows a display example according to the present embodiment. 4A, 4B, and 4C are shown together with the time axis.

  The inventors of the present invention have achieved the present invention by focusing on the following two points.

As can be seen from the target point 1) FIGS. 4A and 4B, depending on site of measuring SpO _2, when the SpO ₂ measured at fingers, the influence of the motion appears in SpO _2, the movement It is often 10 to 30 seconds after the operation. The cause of such a delay is described in Non-Patent Document 1, for example.

Attention point 2) The value of SpO ₂ tends to be dominated by exercise with high intensity.

In view of these, in the present invention, instead of displaying the current SpO ₂ value and the current exercise intensity, the present SpO ₂ value and the current SpO ₂ value within a predetermined period from the current time to a past certain time point are displayed. The maximum value of the exercise intensity is displayed. As a result, the current value of SpO ₂ and the exercise intensity having a dominant effect on the value can be displayed at the same time, so that the medical worker or the user can determine the causal relationship between the SpO ₂ value and the exercise intensity. Can be correctly recognized.

  This will be specifically described with reference to FIG.

The SpO ₂ and pulse rate obtained at time t-0 are 85% and 80 bpm, respectively, and the exercise intensity is 1.5 METs. The SpO ₂ and the pulse rate obtained at time t−1 10 seconds before that are 90% and 90 bpm, respectively, and the exercise intensity is 1.5 METs. The SpO ₂ and the pulse rate obtained at time t-2 10 seconds before this are 97% and 100 bpm, respectively, and the exercise intensity is 4.0METs. The SpO ₂ and pulse rate obtained at time t-4 20 seconds before that are 97% and 65 bpm, respectively, and the exercise intensity is 1.5 METs. Further, the SpO ₂ and the pulse rate obtained 10 seconds after the time point t-0 are 97% and 65 bpm, respectively, and the exercise intensity is 1.5 METs.

  An example of a display image according to the present embodiment is shown in FIG. 4C. Images F1, F2, F3, F4, and F5 are sequentially displayed on the display unit 210 of the tablet terminal 200. At time t-4, the image F1 is displayed, at time t-2, the image F2 is displayed, at time t-1, the image F3 is displayed, at time t-0, the image F4 is displayed, and at time t + 1, the image F5 is displayed. Is displayed.

Each image F1 to F5, and the value of SpO ₂ and pulse rate measurement time point, the maximum value of exercise intensity within a predetermined time period from the measurement time until some point in the past is displayed. In the display image F4, for example time t-0, SpO ₂ and pulse rate "85%, 80 bpm" measurement point maximum exercise intensity in the last 30 seconds "4.0METs" are displayed together. Similarly, the display image F3 of the time t-1, SpO ₂ and pulse rate "85%, 80 bpm" measurement point maximum exercise intensity in the last 30 seconds "4.0METs" are displayed together.

As described above, in the display of the present embodiment, the display values of SpO ₂ and the pulse rate are updated as needed, but the display value of the exercise intensity is fixed to the maximum exercise intensity for the past 30 seconds.

As described above, according to this embodiment, the SpO ₂ and pulse rate, the SpO _2, and the first time point is a measurement point of the pulse rate corresponding than the first time the second time in the past Is displayed together with the maximum exercise intensity within the period up to, the current value of SpO ₂ and the exercise intensity having a dominant effect on the value can be displayed at the same time. The person or the user can correctly recognize the causal relationship between the value of SpO ₂ and the exercise intensity when SpO ₂ decreases.

Note in the above embodiment, SpO ₂ and with pulse rate numbers has dealt with the case of displaying the maximum exercise intensity within the past 30 seconds from the time of measuring the SpO ₂ and pulse rate, not limited thereto, maximum exercise intensity displayed along with SpO ₂ and pulse rate may be the maximum exercise intensity in the period over the past 10 seconds from the time of measurement of SpO ₂ and pulse rate are displayed.

Further, the maximum exercise intensity within a predetermined period in the past from the time when the SpO ₂ and the pulse rate to be displayed are measured may be excluded. Thus, still SpO ₂ and the exercise intensity that does not affect the pulse rate can be prevented from being displayed with the SpO ₂ and pulse rate. For example, the image F2 of the time t-2 in FIG. 4 is "4.0METs" is displayed as the maximum exercise intensity, the time t-2 of the SpO ₂ and pulse rate "97%, 100 bpm" in this It is considered that the effect of the exercise with the maximum exercise intensity “4.0METs” has not yet appeared. Therefore, excluding the SpO ₂ and the maximum exercise intensity in the latest period in which the pulse rate is not affected, the causal relationship between the SpO ₂ value and the exercise intensity can be more correctly recognized.

  In the above-described embodiment, the case where the tablet terminal 200 functions as the life activity display device according to the present invention has been described. However, the pulse oximeter 100 can also function as the life activity display device according to the present invention. That is, the walking speed calculation unit 212, the exercise intensity calculation unit 213, and the storage unit 214 may be provided in the pulse oximeter 100, and the display unit 115 of the pulse oximeter 100 may perform the same display as in the above embodiment. .

  In the above-described embodiment, the case where the present invention is applied to the walking test system 1 has been described. However, the present invention is not limited to this, and may be applied to, for example, a portable activity meter.

Furthermore, in the above-described embodiment, the case where SpO ₂ and the pulse rate are displayed together with the maximum exercise intensity has been described. However, even when SpO ₂ is displayed together with the maximum exercise intensity without displaying the pulse rate. An effect similar to that of the above-described embodiment can be obtained.

  The above-described embodiment is merely an example of the embodiment of the present invention, and the technical scope of the present invention should not be interpreted in a limited manner. That is, the present invention can be implemented in various forms without departing from the gist or the main features thereof.

  The present invention can be applied to, for example, a walking test system.

1 Walking Test System 100 Pulse Oximeter 110 Main Body 111 Light Emitting Circuit 112 Light Receiving Circuit 113, 215 CPU
114, 214 storage unit 115, 210 display unit 116, 211 communication unit 117 operation unit 118 acceleration sensor 120 probe unit 121 light emitting unit 122 light receiving unit 130 cable 200 tablet terminal 211 communication unit 212 walking speed calculation unit 213 exercise intensity calculation unit

Claims (7)

An SpO ₂ acquiring unit for acquiring SpO ₂ of the subject;
An exercise intensity acquisition unit that acquires the exercise intensity of the subject,
A display unit that displays the SpO ₂ together with a maximum exercise intensity in a period from a first time point, which is a measurement time point of the SpO _2, to a _second time point earlier than the first time point,
Equipped with,
The time period from the first time point to the second time point is a time period during which the effect of exercise can appear on SpO ₂ .
Life activity display device. The display unit,
Displaying the value of the SpO ₂ at the time of the measurement and the value of the maximum exercise intensity within the period on the same screen,
The life activity display device according to claim 1. The second time point is a time point that is 10 seconds or more before the first time point,
The life activity display device according to claim 1. The exercise intensity is determined using the number of steps per unit time of the subject,
The life activity display device according to any one of claims 1 to 3. Displaying a pulse rate with said maximum exercise intensity and SpO ₂ ;
The life activity display device according to any one of claims 1 to 4. Calculating a maximum exercise intensity during a period from a first time point, which is a measurement time point of SpO2, to a _second time point earlier than the first time point,
The numerical value of the SpO ₂ at the time of the measurement and the numerical value of the maximum exercise intensity within the period are displayed on the same screen,
The time period from the first time point to the second time point is a time period during which the effect of exercise can appear on SpO ₂ .
Life activity display method. A pulse oximeter for measuring SpO ₂ of the subject;
The measured SpO ₂ and the exercise intensity of the exercise performed by the subject are input, and the SpO ₂ is converted from a first point in time at which the SpO ₂ is measured to a point in time earlier than the first point in time. A terminal for displaying with the maximum exercise intensity within the period up to the time point 2,
Equipped with,
The time period from the first time point to the second time point is a time period during which the effect of exercise can appear on SpO ₂ .
Walking test system.

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