JP6710474B2 - Cortisol concentration estimation device, cortisol concentration estimation method, and program - Google Patents

Description

The present invention relates to a cortisol concentration estimation device, a cortisol concentration estimation method, and a program.

Conventionally, it is known to measure a cortisol concentration from a body fluid such as blood, urine, saliva of a subject using a specialized analyzer. For example, Non-Patent Document 1 describes that the cortisol concentration is measured by a body fluid by the RIA (Radio Immuno Assay) method and the EIA method (Enzyme Immuno Assay) method. Liquid chromatography tandem mass spectrometry is also known as a method for measuring the concentration of cortisol from body fluids. Non-Patent Document 2 describes that there is a negative correlation between the amount of parasympathetic nerve activity of a subject in a high stress state and the cortisol concentration measured from saliva.

Hershel Raff, 1 other, "Circadian rhythm of salivary cortisol, plasma cortisol, and plasma ACTH in end-stage renal disease", Endocrine Connections, October 2012, 2:23-31 Kozo Yoshino, 3 others, "Correlation between salivary cortisol concentration before bedtime and autonomic nervous system activity balance in young men", Stress Science Research 2011, 26, 48-52

When the RIA method or EIA method as described above is used, it may take several days or more to measure the cortisol concentration, and the measurement may not be performed accurately. Further, according to the liquid chromatography tandem mass spectrometry, the cortisol concentration is accurately measured, but it takes several days or longer. Further, in order to estimate the cortisol concentration by correlating with the heartbeat, it is necessary to put the subject in a specific state of high stress and then measure the heartbeat. In Non-Patent Document 2, it has not been confirmed that there is a correlation between the heartbeat and the cortisol concentration in a state other than the high stress state or a time period other than before bedtime, and it is considered to be a future issue. Therefore, there has been a problem that it is difficult to grasp the cortisol concentration quickly and easily in any time period and in a state where high stress is not caused by any of the above methods.

An object of the present invention made in view of such circumstances is to provide a cortisol concentration estimation device, a cortisol concentration estimation method, and a program that can non-invasively and easily estimate the cortisol concentration.

To solve the above problems, cortisol concentration estimation apparatus according to the present invention is a cortisol concentration estimating device for estimating the cortisol concentration subject in a resting heart rate measured every time of the subject And a estimating unit that estimates the cortisol concentration of the subject from the representative value so that the representative value and the cortisol concentration have a positive correlation. Is characterized by.

Also, cortisol estimation apparatus according to the present invention is a cortisol concentration estimating device for estimating the cortisol concentration subject in a resting state, represented in the calculated heart rate for a predetermined time interval for each time of the subject a calculation unit that acquires a value, than said estimate of cortisol concentration in the subject when the representative value of the heart rate of the first value, when the representative value of the second value larger than the first value An estimation unit that estimates the cortisol concentration of the subject such that the cortisol concentration of the subject has a large value.

Also, cortisol estimation method according to the present invention is a cortisol concentration estimation method for estimating the cortisol concentration subject in a resting state, representative of the subject of the time the heart rate measured every predetermined time interval It is characterized by including a step of calculating a value and a step of estimating the cortisol concentration of the subject from the representative value so that the representative value and the cortisol concentration have a positive correlation.

Also, cortisol estimation method according to the present invention is a cortisol concentration estimation method for estimating the cortisol concentration subject in a resting state, represented in the calculated heart rate for a predetermined time interval for each time of the subject calculating a value, than said estimate of cortisol concentration in the subject when the representative value of the heart rate of the first value, the case wherein the representative value of the second value larger than the first value Estimating the cortisol concentration of the subject such that the cortisol concentration of the subject becomes a large value.

Further, the program according to the present invention causes a computer to function as the above cortisol concentration estimation device.

According to the present invention, the cortisol concentration can be estimated non-invasively and easily.

It is a figure which shows an example of the time change of the heart rate calculated from the electrocardiogram. It is a figure which shows the correlation of the typical value of the heart rate at rest, and a cortisol density|concentration. It is a block diagram which shows the structural example of the cortisol density|concentration estimation apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the cortisol density|concentration estimation method which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the structural example of the cortisol concentration estimation apparatus which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows an example of the cortisol density|concentration estimation method which concerns on the 2nd Embodiment of this invention.

In describing the embodiments of the present invention, first, the correlation between the heart rate and the cortisol concentration discovered by the inventors will be described.

In an experiment conducted by the inventors, a heartbeat-related index value related to the heartbeats of 20 subjects in a resting state was measured. In this experiment, the heartbeat-related index value is the heart rate. The inventors also calculated a representative value of heartbeat-related index values, that is, a representative value of heart rate. The representative value is, for example, a value obtained by statistically calculating the heart rate measured within a predetermined time such as an average value or an intermediate value. A known electrocardiograph was used to measure the heart rate. The term "resting state" is used to mean "not performing a task". In other words, it does not mean "absolute rest" in which you lie down and does not move, but it means that you are not performing any tasks, so to speak, "normal conditions."

An electrocardiograph measures a voltage between electrodes attached to a subject. Then, the electrocardiograph calculates the heart rate based on the RR interval, which is the interval between the one R wave and the R wave adjacent to the one R wave. Thereby, the electrocardiograph can measure the time change of the heart rate as shown in FIG.

Further, in this experiment, saliva was collected from each of 20 subjects and the cortisol concentration in saliva was measured while the heartbeat-related index value was measured as described above.

FIG. 2 is a diagram showing the relationship between the cortisol concentration and the representative value of the heart rate. The vertical axis represents the cortisol concentration measured from the saliva of the subject. The horizontal axis is the representative value of the heart rate. As shown in FIG. 2, it can be read that the cortisol concentration increases as the representative value of the heart rate increases. In this way, the inventors have found that there is a positive correlation between the cortisol concentration and the representative value of the heart rate. Note that in this experiment, unlike Non-Patent Document 2, the measurement is performed during the daytime, not before the bedtime. Also, the subject is not under high stress. That is, a positive correlation between the cortisol concentration and the heartbeat-related index value for a subject in an arbitrary state (a state that is not a high stress state) during the daytime period, which was not clarified in Non-Patent Document 2, It was observed. The representative value of the heart rate in this experiment was the average value of the heart rate in a predetermined time period.

The correlation function between the heartbeat-related index value and the cortisol concentration can be derived from the experimental results. The correlation function varies depending on the environment, conditions, etc. of the experiment, but an example is shown in formula (1). In the formula (1), CORT is a cortisol concentration. HR is a representative value of heart rate. In the present invention, the cortisol concentration is calculated using the positive correlation or the correlation function thus derived.

CORT=28.9×HR-1035 Formula (1)

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 3 is a diagram illustrating a configuration example of the cortisol concentration estimation device 1 according to the first embodiment. The cortisol concentration estimation device 1 is a device that estimates the cortisol concentration of a subject in a resting state, and as shown in FIG. 3, an input unit 21, a heartbeat-related index value storage unit 22, a calculation unit 23, and an estimation unit. The unit 24 and the output unit 25 are provided. Further, the cortisol concentration estimation device 1 inputs the information output from the measurement device 4. In addition, the cortisol concentration estimation device 1 outputs information to the presentation device 5.

The measuring device 4 measures the heartbeat-related index value of the subject in a resting state for a predetermined time period and outputs it to the cortisol concentration estimating device 1. The heartbeat-related index value is an index value related to the heartbeat. The predetermined time period is a time (for example, 60 seconds) in which the representative value of the heartbeat-related index values calculated by the calculation unit 23 is considered to effectively indicate the state of the subject. The representative value is a value obtained by performing a statistical calculation on a measured time-related index value for a predetermined time period such as an average value or an intermediate value. In the present embodiment, an example in which the heartbeat-related index value is the heart rate will be described. In this case, the measuring device 4 measures the heart rate and sequentially outputs the measured heart rate to the cortisol concentration estimating device 1.

Each configuration included in the cortisol concentration estimation device 1 will be described in detail.

The input unit 21 inputs the heartbeat-related index value for each time, which is measured by the measuring device 4 for a predetermined time period and is sequentially output. Specifically, the input unit 21 inputs time-series data of heartbeat-related index values. More specifically, the input unit 21 inputs time-series data of heart rate.

The heartbeat-related index value storage unit 22 may include any storage device such as a semiconductor storage device and a magnetic storage device, or may include a plurality of types of storage devices. The heartbeat-related index value storage unit 22 stores time-series data of heartbeat-related index values measured by the measuring device 4 for a predetermined time period and input by the input unit 21. Specifically, the heartbeat-related index value storage unit 22 stores the heartbeat-related index value continuously measured in the predetermined time period and the time at which the heartbeat-related index value is measured in association with each other. The time may be the elapsed time from the start time.

The calculation unit 23 calculates a representative value of the heartbeat-related index values based on the time-series data of the heartbeat-related index values in the predetermined time section stored in the heartbeat-related index value storage unit 22.

The estimation unit 24 estimates the cortisol concentration from the representative value of the heartbeat-related index values so that the predetermined representative value of the heartbeat-related index value and the cortisol concentration have a positive correlation with each other. Specifically, when the representative value is calculated by the calculation unit 23, the estimation unit 24 makes the estimated value of the cortisol concentration have a positive correlation with the representative value, that is, the larger the representative value, the more the cortisol is. The cortisol concentration is estimated to indicate that the concentration estimate is large. Alternatively, the estimation unit 24 determines that the estimated value of the cortisol concentration when the representative value is the second value larger than the first value is larger than the estimated value of the cortisol concentration when the representative value is the first value. Cortisol concentration is estimated so that For example, the estimation unit 24 estimates the cortisol concentration based on a positive correlation function related to the representative value of the predetermined heartbeat-related index values. An example of the positive correlation function is to estimate the cortisol concentration using the positive correlation function represented by the above equation (1).

The output unit 25 outputs the cortisol concentration estimated by the estimation unit 24 to the presentation device 5.

The presentation device 5 presents information indicating the cortisol concentration estimated by the estimation unit 24 and output by the output unit 25. For example, the presentation device 5 may display the cortisol concentration on the display, or may display an arbitrary index corresponding to the cortisol concentration on the display. Further, the presentation device 5 may output a sound indicating the cortisol concentration.

Next, a method for estimating the cortisol concentration by the cortisol concentration estimation device 1 will be described with reference to FIG. FIG. 4 is a flowchart showing an example of the method for estimating the concentration of cortisol.

First, the input unit 21 inputs a heartbeat-related index value for each time measured by the measuring device 4 for a predetermined time period (step S41).

Next, the heartbeat-related index value storage unit 22 stores the heartbeat-related index value for each time input in step S41 (step S42).

Next, the calculation unit 23 calculates a representative value of the heartbeat-related index values in the predetermined time section from the heartbeat-related index values for each time stored in the heartbeat-related index value storage unit 22 (step S43). An example of the representative value is an average value of the heartbeat-related index values within the predetermined time section, but the representative value is not limited to this and may be any value that represents the heartbeat-related index value within the predetermined time section.

Next, the estimation unit 24 estimates the cortisol concentration based on the representative value calculated in step S43 so as to have a positive correlation with the representative value (step S44). For example, the cortisol concentration is estimated using a predetermined positive correlation or a positive correlation function with respect to the representative value. When the cortisol concentration estimated by the estimation unit 24 when the representative value is the first value is the first cortisol concentration, when the representative value is the second value larger than the first value, the cortisol concentration estimated by the estimation unit is Is estimated by the estimation unit 24 so that the second value is larger than the first cortisol concentration.

Next, the output unit 25 outputs the cortisol concentration estimated in step S44 to the presentation device 5 (step S45). The presentation device 5 can present the cortisol concentration output from the output unit 25.

It should be noted that a computer can be preferably used to function as the above-described cortisol concentration estimation device 1, and such a computer executes a program describing the processing content for realizing each function of the cortisol concentration estimation device 1 of the computer. It can be realized by storing it in a database and reading and executing this program by the CPU of the computer.

Further, the program may be recorded in a computer-readable medium. The computer readable medium can be used for installation on a computer. Here, the computer-readable medium in which the program is recorded may be a non-transitory recording medium. The non-transitory recording medium is not particularly limited, but may be a recording medium such as a CD-ROM or a DVD-ROM.

As described above, according to the first embodiment, the cortisol concentration estimation device 1 is based on the discovery of the natural law that a positive correlation is established between the representative value of the heartbeat-related index value and the cortisol concentration, The cortisol concentration of the subject is estimated from the representative value calculated by the calculation unit 23. Therefore, the cortisol concentration estimation device 1 can estimate the cortisol concentration more quickly than in the case where the measurement is performed using body fluid as in the related art. Further, since the heartbeat-related index value is measured non-invasively, the cortisol concentration estimation device 1 can easily estimate the cortisol concentration.

(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described in detail with reference to the drawings. In the present embodiment, whether or not to propose meditation to the subject is determined based on the “cortisol concentration” estimated by the same method as in the first embodiment.

It is known that human cortisol levels change during the day. In addition, it is known that when the amount of change in cortisol concentration during the day is small, the patient may be in a depressed state (reference document 1). Furthermore, researches by the inventors have found that different kinds of meditation have different effects on humans. Specifically, intensive meditation tends to activate parasympathetic nerve activity, and insight meditation tends to activate sympathetic nerve activity. The research was presented in "Mindfulness Research: Effects of Intensive Meditation and Insight Meditation on the Autonomic Nervous System and Endocrine System" at the 40th Annual Meeting of the Japanese Society of Neuroscience.
(Reference 1) Ma-Li Wong et al.: Pronounced and sustained central hypernoradrenergic function in major depression with melancholic features: Relation to hypercortisolism and corticotropin-releasing hormone, Medical Sciences Vol. 97, No.1, pp.325-330. (2000).

Combining these findings, depressive conditions may be present when cortisol levels are less diurnal, and in this case, the use of insight meditation, which has the effect of activating the sympathetic nerve, can improve the depressive state. Be expected. In the present embodiment, based on such knowledge, it is determined whether or not to propose meditation suitable for the mental state of the subject.

FIG. 5 shows a configuration example of the cortisol concentration estimation device 2 according to the second embodiment. As shown in FIG. 5, the cortisol concentration estimation device 2 includes a cortisol concentration estimation unit 20, an output unit 25, a cortisol concentration storage unit 26, and a determination unit 27. The cortisol concentration estimation unit 20 includes an input unit 21, a heartbeat-related index value storage unit 22, a calculation unit 23, and an estimation unit 24, similarly to the cortisol concentration estimation device 1 of the first embodiment. In addition, the same reference numerals are given to the same configuration blocks as those in the first embodiment, and the description will be appropriately omitted.

The measuring device 4 measures the heartbeat-related index value at different times of the day.

The cortisol concentration estimation unit 20 estimates the cortisol concentration of the subject for each heartbeat-related index value measured by the measurement device 4 at different times. The detailed method of estimation by the cortisol concentration estimation unit 20 is the same as the estimation method by the cortisol concentration estimation device 1 of the first embodiment.

The cortisol concentration storage unit 26 stores the cortisol concentration estimated by the cortisol concentration estimation unit 20. Specifically, the cortisol concentration storage unit 26 stores the cortisol concentration in association with the time at which the heartbeat-related index value used to estimate the cortisol concentration is measured. The time may be any time as long as it can specify the time interval in which the representative value of the heartbeat-related index values is calculated. The time may be, for example, the time at which the measurement was started in the time section in which the representative value of the heartbeat-related index value was obtained, or the measurement was ended in the time section in which the representative value of the heartbeat-related index value was obtained It may be the time of day. In the present embodiment, the cortisol concentration estimation unit 10 estimates the cortisol concentration for a plurality of different time intervals from the heartbeat-related index values measured within the time intervals. Then, the cortisol concentration storage unit 26 stores a plurality of estimated cortisol concentrations.

The determination unit 27 determines whether to propose meditation based on the amount of change in the cortisol concentration at a plurality of different times (time intervals) estimated by the estimation unit 24. Generally, meditation includes intensive meditation and insight meditation. Intensive meditation is meditation that focuses on one part of the body (for example, the entrance of the nose), and insight meditation is meditation that focuses on every part of the body.

Specifically, based on the cortisol concentrations estimated for a plurality of different time sections of a day stored in the cortisol concentration storage unit 26, the determination unit 27 proposes meditation based on the index. Determine whether or not. For example, a difference (change amount) in cortisol concentration between adjacent time intervals is calculated to obtain a series of change amounts, and if all the values in the change amount sequence are less than a predetermined threshold value, it is determined that insight meditation is proposed. If not, it is determined not to propose meditation. The fact that each value in the series of changes in cortisol concentration is less than the predetermined threshold value indicates that the amount of change in cortisol concentration during one day is small, that is, the change in cortisol concentration within a day is small. As described above, when there is little fluctuation in the cortisol concentration during the day, there is a possibility of depression, and since improvement is expected by insight meditation, the judgment unit 27 proposes insight meditation.

When the determination unit 27 determines that the insight meditation is proposed, the output unit 25 outputs the meditation suggestion information that suggests the meditation to the subject to the presentation device 5. The meditation suggestion information is, for example, information such as “please perform insight meditation”, instruction voice or image for promoting insight meditation, or the like. Alternatively, when the determination unit 27 determines to propose the insight meditation, the output unit 25 outputs the cortisol concentration estimated by the cortisol concentration estimation unit 20 to the presentation device 5 in addition to the meditation suggestion information to perform the insight meditation. If it is determined not to propose, only the cortisol concentration estimated by the cortisol concentration estimation unit 20 may be output to the presentation device 5.

When the output unit 25 outputs the meditation proposal information, the presentation device 5 presents the meditation proposal information to the target person. For example, the presentation device 5 can present the meditation proposal information by outputting a voice. Further, for example, the presentation device 5 can present the meditation proposal information by displaying on the display. Alternatively, the cortisol concentration output from the output unit 25 may be displayed on the display in time series, and may be displayed on the display together with a visual effect that calls attention when the cortisol concentration corresponding to the meditation suggestion information is displayed. For example, it may be a visual effect of changing the background color of the display screen or causing it to blink, or a visual effect of displaying a text message such as "Please do insight meditation".

Next, an example of a cortisol concentration estimation method by the cortisol concentration estimation device 2 will be described with reference to FIG. FIG. 6 is a flowchart showing an example of the method for estimating the concentration of cortisol.

First, the cortisol concentration estimation unit 20 estimates the cortisol concentration of the subject (step S51). The details of the processing by the cortisol concentration estimation unit 20 in step S51 are the same as the processing of the cortisol concentration estimation device 1 in the first embodiment.

Next, the cortisol concentration estimated in step S51 is stored in the cortisol concentration storage unit 26 (step S52).

Next, the determination unit 27 determines whether or not the cortisol concentration for the target person for a predetermined time is already stored in the cortisol concentration storage unit 26 (step S53).

When it is determined in step S53 that the cortisol concentration for the subject is not stored in the cortisol concentration storage unit 26, the process returns to step S51 to estimate the cortisol concentration for a new time.

On the other hand, in step S53, when it is determined that the cortisol concentration for the subject for the predetermined time is stored in the cortisol concentration storage unit 26, the determination unit 27 determines the difference in the cortisol concentration between adjacent times ( The change amount) is calculated to calculate the change amount series (step S54).

Next, the determination unit 27 determines whether or not each of the change amounts calculated in step S54 is less than the threshold value (step S55).

In step S55, if there is a change amount equal to or greater than the threshold value among the change amounts, the cortisol concentration estimation device 2 ends the process.

On the other hand, when it is determined in step S55 that all the variations are less than the threshold value, the output unit 25 outputs the meditation suggestion information to the presentation device 5 (step S56). The presentation device 5 can present the meditation suggestion information output from the output unit 25.

It should be noted that a computer can be preferably used to function as the cortisol concentration estimation device 2 described above, and such a computer stores a program describing the processing content for realizing each function of the cortisol concentration estimation device 2 of the computer. It can be realized by storing it in a database and reading and executing this program by the CPU of the computer.

Further, the program may be recorded in a computer-readable medium. The computer readable medium can be used for installation on a computer. Here, the computer-readable medium in which the program is recorded may be a non-transitory recording medium. The non-transitory recording medium is not particularly limited, but may be a recording medium such as a CD-ROM or a DVD-ROM.

As described above, according to the second embodiment, the cortisol concentration estimation device 1 determines whether or not to suggest meditation to the subject based on the cortisol concentration, and the presentation device 5 provides the meditation suggestion information. Present. Therefore, the cortisol concentration estimation device 1 proposes meditation promptly as compared with the case of determining the depression state of the subject based on the cortisol concentration measured using body fluid and proposing meditation as in the related art. You can Along with this, the subject can perform meditation at an early stage in order to improve the depressed state. Further, since the heartbeat-related index value is measured non-invasively, the cortisol concentration estimation device 2 can easily estimate the cortisol concentration, and can easily propose meditation accordingly.

In the first embodiment, the cortisol concentration estimation device 1 may include the measurement device 4 as a measurement unit. In this case, the measurement unit of the cortisol concentration estimation device 1 measures the heart rate of the subject. Similarly, in the second embodiment, the cortisol concentration estimation unit 20 may include the measurement device 4 as a measurement unit.

Further, in the first embodiment, the cortisol concentration estimation device 1 may include the presentation device 5 as a presentation unit. In this case, the presentation unit presents the cortisol concentration. Similarly, in the second embodiment, the cortisol concentration estimation device 1 may include the presentation device 5 as a presentation unit. In this case, the presentation unit presents the meditation proposal information.

Although the above embodiments have been described as representative examples, it will be apparent to those skilled in the art that many modifications and substitutions can be made within the spirit and scope of the present invention. Therefore, the present invention should not be construed as being limited by the above-described embodiments, and various modifications and changes can be made without departing from the scope of the claims.

1, 2 Cortisol concentration estimation device 4 Measuring device 5 Presenting device 20 Cortisol concentration estimation unit 21 Input unit 22 Heart rate related index value storage unit 23 Calculation unit 24 Estimating unit 25 Output unit 26 Cortisol concentration storage unit 27 Determination unit

Claims (8)

A cortisol concentration estimation device for estimating the cortisol concentration of a subject,
A calculation unit that calculates a representative value in a predetermined time interval heart rate measured every time of the subject,
An estimation unit that estimates the cortisol concentration of the subject from the representative value so that the representative value and the cortisol concentration have a positive correlation,
An apparatus for estimating cortisol concentration, comprising: A cortisol concentration estimation device for estimating the cortisol concentration of a subject,
A calculation unit that calculates a representative value of the calculated heart rate for a predetermined time interval for each time of the subject,
Than the estimated value of the cortisol levels of the subject when the representative value of the heart rate first value, cortisol levels of the subject when the second value is greater than the representative value is the first value is greater An estimation unit for estimating the cortisol concentration of the subject so as to have a value,
An apparatus for estimating cortisol concentration, comprising: Based on the cortisol concentration for a plurality of different predetermined time period estimated by the estimation unit, a determination unit that determines whether to propose meditation to the subject,
The cortisol concentration estimation device according to claim 1 or 2, further comprising: The determining unit determines to propose the meditation when a change amount of the cortisol concentration estimated for each of the plurality of different predetermined time intervals is less than a threshold value over the plurality of different time intervals. The cortisol concentration estimation device according to claim 3. The determination unit determines to propose the meditation when each of the amounts of change in the cortisol concentrations estimated for each of the plurality of different predetermined time intervals in each adjacent time interval is less than a predetermined threshold value. The cortisol concentration estimation device according to claim 3, wherein A method for estimating cortisol concentration of a subject, comprising:
Calculating a representative value of the measured heart rate for a predetermined time interval for each time of the subject,
Estimating the cortisol concentration of the subject from the representative value so that the representative value and the cortisol concentration have a positive correlation;
A method for estimating cortisol concentration, which comprises: A method for estimating cortisol concentration of a subject, comprising:
Calculating a representative value of the calculated heart rate for a predetermined time interval for each time of the subject,
Than the estimated value of the cortisol levels of the subject when the representative value of the heart rate first value, cortisol levels of the subject when the second value is greater than the representative value is the first value is greater And a step of estimating the cortisol concentration of the subject so that the value becomes a value. A program for causing a computer to function as the cortisol concentration estimation device according to any one of claims 1 to 5.

Images