JP6395769B2 - Blood flow measurement device, calculation system, calculation method, calculation program, blood flow measurement method, and blood flow measurement program - Google Patents

Description

  The present invention relates to a blood flow measurement device, a calculation system, a calculation method, a calculation program, a blood flow measurement method, and a blood flow measurement program.

  Conventionally, a technique for determining a stress state from amylase in saliva is known (for example, Patent Document 1). Here, the biological reaction caused by the action of the autonomic nerve is called stress.

JP 2002-168860 A

  However, collecting saliva every time the state of the autonomic nerve is measured places a heavy burden on the subject.

  An object of the present invention made in view of such circumstances is to provide a blood flow measurement device, a calculation system, a calculation method, a calculation program, a blood flow measurement method, and a blood flow measurement program capable of measuring the state of an autonomic nerve. There is to do.

One aspect of the blood flow measurement device is:
A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow wave height;
A light receiving unit that receives scattered light from the test site;
A blood flow measurement unit for measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
A control unit that calculates the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
Is provided.
Moreover, the blood flow measuring device of one aspect is
A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow;
A blood flow measurement unit for measuring blood flow;
A controller that calculates the state of the autonomic nerve based on the stored relationship and the measured blood flow,
The relationship between the state of the autonomic nerve and the blood flow is calculated based on the relationship between the target amylase measured when a stimulus is applied to the target and the measured blood flow.

One aspect of the calculation system is:
A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow wave height;
A light receiving unit that receives scattered light from the test site;
A blood flow measurement unit for measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
A control unit that calculates the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
Is provided.
Moreover, the calculation system of one aspect is
An amylase measuring unit for measuring the amylase of the subject when the subject is stimulated;
A blood flow measurement unit for measuring blood flow;
Based on the relationship between the measured amylase and the measured blood flow, a control unit that calculates the relationship between the state of the autonomic nerve and the blood flow,
Is provided.

One aspect of the blood flow measurement method is:
Memorizing the relationship between the state of the autonomic nerve and the blood flow wave height;
Receiving scattered light from the test site;
Measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
Calculating the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
Is provided.
Moreover, the blood flow measurement method according to one aspect includes:
Memorizing the relationship between the state of the autonomic nerve and blood flow;
Measuring blood flow;
Calculating an autonomic state based on the stored relationship and the measured blood flow,
The relationship between the state of the autonomic nerve and the blood flow is a relationship between the target amylase measured when a stimulus is given to the target and the measured blood flow.

One aspect of the blood flow measurement program is:
On the computer,
Receiving scattered light from the test site;
Measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
Calculating the state of the autonomic nerve based on the blood flow wave height and the relationship between the state of the autonomic nerve stored in the storage unit and the blood wave wave height;
Is executed.
Moreover, the blood flow measurement program of one aspect is
On the computer,
Measuring blood flow;
Based on the blood flow and the relationship between the target amylase and the measured blood flow measured when a stimulus is applied to the object stored in the storage unit, the state of the target autonomic nerve is determined. A calculating step;
Is executed.

  According to the blood flow measurement device, the calculation system, the calculation method, the calculation program, the blood flow measurement method, and the blood flow measurement program according to an embodiment of the present disclosure, it is possible to measure the state of the autonomic nerve.

It is a schematic structure figure of a calculation system concerning one embodiment of this indication. It is AA sectional drawing of FIG. It is a functional block diagram showing a schematic structure of a calculation system according to an embodiment of the present disclosure. It is a figure which shows the measurement result of the blood flow volume, blood flow wave height, and amylase density | concentration of object. It is a figure which shows the measuring method of blood flow wave height. It is a figure which shows correlation with blood flow volume and blood flow wave height, and an amylase density | concentration. It is a figure which shows the measurement result when the blood-flow wave height and amylase density | concentration of another object are measured. 5 is a flowchart illustrating an example of processing executed by a calculation system according to an embodiment of the present disclosure.

  FIG. 1 is an external perspective view of a calculation system S in a state where a blood flow measurement device 1 according to an embodiment of the present disclosure is attached to a target. The blood flow measurement device 1 is a wearable device that is worn so as to sandwich the tragus of the right ear or the left ear of the subject, for example. The target is, for example, a patient, a subject, a user, or the like. Although the shape of the blood flow measuring device 1 is arbitrary, for convenience of explanation, the shape of the blood flow measuring device 1 according to the present embodiment will be described as shown in FIG.

  The calculation system S includes a blood flow measuring device 1, a terminal device 2, and an amylase measuring device 3. The blood flow measuring device 1 is connected to the terminal device 2 by wire. The blood flow measurement device 1 may be connected to the terminal device 2 by wireless or a combination of wired and wireless. The terminal device 2 is connected to the amylase measuring device 3 by wire. The terminal device 2 may be connected to the amylase measuring device 3 by wireless or a combination of wired and wireless.

  FIG. 2 is a cross-sectional view taken along the line AA in FIG. In order to prevent the blood flow measuring device 1 from compressing the tragus, a stretchable and flexible material may be provided between the blood flow measuring device 1 and the tragus. This material is, for example, a rubber material such as silicon rubber or natural rubber. The blood flow measurement device 1 includes a transmission sensor 12 and a reflection sensor 13 described later.

  FIG. 3 is a functional block diagram showing a schematic configuration of the calculation system S.

  The blood flow measurement device 1 includes a control unit 11, a transmission type sensor 12, a reflection type sensor 13 (blood flow measurement unit 13), a storage unit 14, and a communication unit 15.

  The control unit 11 is a processor that controls and manages the entire blood flow measurement device 1. The control unit 11 includes a processor such as a CPU (Central Processing Unit) that executes a program that defines a control procedure. The program is stored, for example, in the storage unit 14 or an external storage medium connected to the blood flow measurement device 1. The control part 11 may implement | achieve the operation | movement demonstrated below by cooperating with the said program. The control unit 11 measures blood flow based on the biometric output obtained by at least one of the transmission sensor 12 and the reflection sensor 13. In the present embodiment, blood flow measurement is measurement of blood flow volume and blood flow wave height. The blood flow wave height indicates the power of one pulsation of the heart and is a value serving as an index of vasodilation. The control unit 11 calculates the state of the autonomic nerve by a method described later.

  Here, the autonomic nerve referred to in the present disclosure refers to a nerve that controls the function of the body in response to a stimulus. This stimulus includes various things such as ambient temperature change, predetermined work, information, physical thing, and mental thing. The autonomic nerve is composed of two types, a sympathetic nerve and a parasympathetic nerve. The sympathetic nerve is a nerve that works when it is active, when it is tense, or when it feels an external stimulus. The parasympathetic nerve is a nerve that works when sleeping or relaxing. The state of the autonomic nerve of this indication means the state of a sympathetic nerve and a parasympathetic nerve. Note that the state of the autonomic nerve of the present disclosure may be only the state of the sympathetic nerve or the parasympathetic nerve. The biological reaction caused by the action of autonomic nerves is also called stress. The biological reaction caused by the action of the sympathetic nerve of the autonomic nerve is also called stress. This biological reaction includes physical or mental things. Stimulation is thought to generate an excitement signal of the sympathetic nervous system. The sympathetic nervous system excitement signal is thought to increase the concentration of amylase in the body. Therefore, by measuring amylase, the state of the target autonomic nerve can be measured.

  The transmission type sensor 12 irradiates the target tragus with measurement light and receives transmitted light transmitted through the tissue inside the tragus. The transmission sensor 12 transmits a photoelectric conversion signal of the received transmitted light to the control unit 11 as a biological measurement output. The transmissive sensor 12 includes a light emitting unit 12a and a light receiving unit 12b.

  The light emitting unit 12 a emits laser light based on the control of the control unit 11. The light emitting unit 12a irradiates, for example, a laser beam having a wavelength capable of detecting a predetermined component contained in blood as a measurement light on a test site of the target tragus. The light emitting unit 12a is configured by, for example, an LD (Laser Diode).

  The light receiving unit 12b receives the transmitted light of the measurement light from the site to be examined. The light receiving unit 12b is configured by, for example, a PD (photodiode). The transmission sensor 12 transmits a photoelectric conversion signal of the transmitted light received by the light receiving unit 12b to the control unit 11 as a biological measurement output.

  The transmission sensor 12 according to the present embodiment irradiates a test site with laser beams having two different wavelengths. The transmissive sensor 12 according to the present embodiment includes two LDs. Specifically, the light emitting unit 12a includes an LD that emits laser light having a wavelength of about 660 nm and an LD that emits laser light having a wavelength of about 940 nm.

  The reflective sensor 13 irradiates the tragus with measurement light and receives reflected light (scattered light) from the tissue inside the tragus. The reflective sensor 13 transmits a photoelectric conversion signal of the received scattered light to the control unit 11 as a biological measurement output. The reflective sensor 13 includes a light emitting unit 13a and a light receiving unit 13b.

  The light emitting unit 13 a emits laser light based on the control by the control unit 11. For example, the light emitting unit 13a irradiates the test site with laser light having a wavelength capable of detecting a predetermined component contained in blood as measurement light. The light emitting unit 13a is configured by, for example, one LD (Laser Diode).

  The light receiving unit 13b receives the scattered light of the measurement light from the test site. The light receiving unit 13b is configured by, for example, a PD (photodiode). The reflective sensor 13 transmits a photoelectric conversion signal of scattered light received by the light receiving unit 13b to the control unit 11 as a biological measurement output.

  The control unit 11 calculates the blood flow volume and blood flow wave height at the test site based on the biometric measurement output received from the reflective sensor 13. The control unit 11 measures the blood flow volume and the blood flow wave height using the Doppler shift. In the present embodiment described below, as an example, the blood flow volume and the blood flow wave height used for calculating the state of the autonomic nerve are described as being measured using the reflective sensor 13. The reflective sensor 13 is also referred to as a blood flow measurement unit 13 in the present embodiment. As an alternative example, the blood flow volume and blood flow wave height used for calculating the state of the autonomic nerve may be measured using the transmission sensor 12.

  The storage unit 14 is composed of a semiconductor memory. The storage unit 14 may be configured with a magnetic memory or the like. The storage unit 14 stores various information, a program for operating the blood flow measurement device 1, and the like. The storage unit 14 also functions as a work memory. The storage unit 14 stores, for example, the blood flow volume and blood flow wave height calculated by the control unit 11 based on the biological measurement output acquired by the blood flow measurement unit 13. The storage unit 14 stores the relationship between the state of the autonomic nerve and the blood flow calculated by the control unit 11.

  The communication unit 15 is an interface that transmits and receives information to and from the terminal device 2 and the like via a network. The communication unit 15 may have a communication function by wire, wireless, or a combination thereof. The wired communication function may be USB or LAN. The wireless communication function may be LTE (Long Term Evolution), wireless LAN (Local Area Network), infrared communication, or the like. By mounting such a communication function, the blood flow measurement device 1 can be operated and controlled from an external operation terminal, for example. Moreover, the blood flow measuring device 1 can transmit various measured information to an external device.

  The terminal device 2 is an arbitrary terminal device such as a smartphone, a feature phone, a PC (Personal Computer), or a tablet PC.

  The terminal control unit 21 is a processor that controls and manages the entire terminal device 2. The terminal control unit 21 includes a processor such as a CPU that executes a program that defines a control procedure. The program is stored in, for example, a storage unit of the terminal device 2 or an external storage medium connected to the terminal device 2.

  The display unit 22 is a liquid crystal display. The display unit 22 may be a display device such as an organic EL display or an inorganic EL display. The display unit 22 displays, for example, blood flow measurement results by the blood flow measurement unit 13, information on the start of measurement of amylase concentration, information on the state of autonomic nerves, and the like. The information on the state of the autonomic nerve includes the sympathetic state, parasympathetic state, tension, relaxation, pleasantness, unpleasantness, fun, pain, fatigue, comfort, etc. of the user who uses the blood flow measuring device 1 And information such as physical condition.

  The input unit 23 receives an operation input from a target. The input unit 23 includes, for example, operation buttons (operation keys). The input unit 23 may be configured by a touch panel, and an operation key that receives an operation input from the target may be displayed on a part of the display unit 22 to receive a touch operation input by the target.

  The communication unit 24 is an interface that transmits and receives information to and from the blood flow measurement device 1 and the amylase measurement device 3 via a network. Since the configuration of the communication unit 24 is the same as or similar to that of the communication unit 15, the description thereof is omitted.

  The amylase measuring device 3 includes an amylase measuring unit 31. The amylase measuring unit 31 measures amylase contained in saliva collected from the subject. In the present embodiment, measurement of amylase is measurement of amylase concentration. In the present embodiment, the amylase measuring unit 31 measures the amylase concentration of the subject when the subject is stimulated. The amylase measuring device 3 may include a display unit that displays the measured amylase concentration. Further, the amylase measuring device 3 can output the measured amylase concentration to the terminal device 2.

  Hereinafter, a method for calculating the state of the autonomic nerve using the calculation system S according to the present embodiment will be described in detail. In this embodiment, the subject performs a test for measurement of blood flow, blood flow height, and amylase concentration. In this embodiment, the unit of blood flow volume and blood flow wave height is [ml / min], and the unit of amylase concentration is [kU / l]. The unit of blood flow volume and blood flow wave height may be [ml / s], [l / h], or the like.

  It is generally known that amylase concentration reflects the state of autonomic nerves. More specifically, it is generally known that amylase concentration reflects the state of sympathetic nervous system activity. Therefore, the amylase concentration increases if the subject receives an unpleasant stimulus, and the amylase concentration decreases if the subject receives a comfortable stimulus. For this reason, the relationship between the blood flow and the state of the autonomic nerve becomes clear by associating the blood flow with amylase. As a result of the relationship being clarified, it is possible to calculate the state of the autonomic nerve by measuring the blood flow without measuring the amylase concentration. Below, the calculation method of the state of the autonomic nerve by a test is demonstrated in detail.

  Subjects will receive explanations of precautions during the test. For example, precautions should never be spoken and the head should not be moved.

  Next, the subject wears the blood flow measuring device 1 on the tragus. As an alternative example, the mounting location of the blood flow measurement device 1 may be the subject's nose or forehead. The blood flow measuring device 1 is connected to the terminal device 2 based on an operation by a subject or the like, and the terminal device 2 is connected to the amylase measuring device 3.

  The blood flow measurement unit 13 of the blood flow measurement device 1 starts measuring the blood flow of the target based on an operation on the blood flow measurement device 1 by the target. At this time, the display unit 22 of the terminal device 2 connected to the blood flow measurement device 1 performs a display prompting the subject to relax and rest so that the reaction of the amylase concentration becomes clear. Specifically, the display unit 22 may perform a display that prompts the user to wear an eye mask, or may perform a display that prompts the user to listen to music. The terminal device 2 may output music from the audio output unit of the terminal device 2.

  When a predetermined time (for example, 10 minutes) has elapsed since the start of blood flow measurement, the control unit 11 of the blood flow measurement device 1 notifies the terminal device 2 through the communication unit 15. The blood flow measurement unit 13 continues to measure blood flow thereafter.

The terminal control unit 21 of the terminal device 2 that has received the notification that the predetermined time has elapsed starts a test to start stimulating the subject for a predetermined time (for example, 10 minutes) after receiving the notification. The test is a brain training test or the like that can be performed with only one hand, and is specifically as follows.
・ Calculation ・ Puncture of operation symbols ・ Mental calculation of day of the week ・ How to read Kanji ・ Search for the maximum or minimum number from the number group ・ Number of characters when all displayed sentences are hiragana ・ In the figure group Two-choice quizzes such as the number of the figure that exists, the color judgment of the character, the winning or losing of Janken

  The terminal control unit 21 of the terminal device 2 that has received the notification that the predetermined time has passed notifies the amylase measuring device 3 that the predetermined time has passed. In addition, the display unit 22 of the terminal device 2 performs a display prompting to measure the amylase concentration in saliva using the amylase measuring device 3. The display unit 22 performs this display at a predetermined interval (for example, every 2 minutes) for a predetermined time (for example, 20 minutes) after receiving notification that the predetermined time has elapsed. A subject who visually recognizes the display operates the amylase measuring device 3.

  A method for measuring the amylase concentration using the amylase measuring device 3 may be, for example, a method in which a predetermined sheet is put in the lower part of the tongue to attach saliva, and then the sheet is inserted into the amylase measuring device 3 to perform measurement. . The subject operates the terminal device 2 and receives a test, and simultaneously operates the amylase measuring device 3 to measure the amylase concentration.

  When the terminal control unit 21 determines that the test has been performed for a predetermined time (for example, 10 minutes), the display unit 22 performs a display prompting to relax and rest for a predetermined time (for example, 10 minutes). While relaxing, the amylase measuring device 3 continues to measure the amylase concentration based on the operation by the subject.

  The amylase measuring device 3 transmits the measurement result to the blood flow measuring device 1 via the terminal device 2 when the measurement of the amylase concentration is completed after a predetermined time. When the amylase measuring device 3 and the terminal device 2 are not connected, as an alternative, the amylase measuring device 3 may perform a display prompting the user to input the measurement result to the terminal device 2.

  A graph showing the transition of the measured blood flow (blood flow volume and blood flow wave height) and amylase (amylase concentration) is shown in FIG. The blood flow wave height is a value obtained by partially correcting the measured value as follows.

  FIG. 5A is a diagram showing a graph of blood flow measured by the blood flow measurement unit 13. The control unit 11 of the blood flow measurement device 1 smoothes the graph as shown in FIG. 5B by multiplying the value of the graph by a moving average. Next, the control unit 11 compares the blood flow volume at an arbitrary coordinate with the blood flow volume before and after that, and if the former is smaller than the latter, the blood flow volume at the arbitrary coordinate is set as a minimum value. The minimum value coordinate is indicated by P2. Moreover, the control part 11 sets the maximum value of the blood flow volume from the minimum value coordinate P2 in a certain 1 beat to the minimum value coordinate in the following 1 beat as a maximum value. The maximum coordinate is indicated by P1. The control unit 11 sets the difference between the maximum value and the minimum value at a certain beat as the blood flow wave height H. Thus, the calculation of the blood flow wave height requires at least a time interval of one heartbeat. Therefore, in the description of the blood flow wave height graph and the like described below, the blood flow wave height at time t refers to the blood flow wave height at a time interval of one beat including at least time t.

  Referring to FIG. 4 again, the time zone in which the blood flow measurement device 1 measures blood flow is from time t0 to time t32, and the time zone in which the terminal control unit 21 performs testing is from time t10 to time t20. In addition, the time zone in which the amylase measuring device 3 measures the amylase concentration is from time t10 to time t30. The difference between time tn and time t (n + 1) is 1 minute.

  Since the amylase concentration has a peak (maximum value) at time t24, the saliva at this time indicates that the activity of the sympathetic nerve of the subject is maximum. Since the response of the amylase concentration to the sympathetic nerve activity takes 1 to several minutes, the actual sympathetic nerve activity of the subject is actually the maximum before time t24.

  Next, this embodiment will be described with reference to FIG. The amylase concentration graph is translated in the upper left direction so that the coordinate C3 at which the amylase concentration reaches a peak coincides with the coordinate C1 at which the blood flow reaches a peak. In this case, the tendency of the amylase concentration graph and the blood flow graph are substantially the same. This is the same or similar when the amylase concentration graph is translated and related so that the coordinate C3 at which the amylase concentration reaches a peak coincides with the coordinate C2 at which the blood flow wave height reaches a peak. According to FIG. 6, the peak of amylase concentration is delayed by 6 minutes from the peak of blood flow wave height. Therefore, for example, the coordinate C6 is associated with the coordinates C4 and C5. In this way, the control unit 11 can associate each of the coordinates on the graph of blood flow volume or blood flow wave height with the coordinates on the graph of amylase concentration after 6 minutes.

  As described above, amylase concentration is known to reflect the state of autonomic nerves. Therefore, under a situation where no external stimulus such as exercise or massage is applied, the transition of blood flow volume or blood wave height has a certain correlation with the transition of the state of the autonomic nerve. For example, since the amylase concentration is minimum at time t10, the control unit 11 determines that the activity of the target sympathetic nerve is minimum at time t4. Further, since the amylase concentration is at the peak at time t24, the control unit 11 determines that the activity of the target sympathetic nerve is maximum at time t18.

As described above, the control unit 11 determines the state of the autonomic nerve and the blood flow based on the relationship between the target amylase measured when the target is stimulated and the blood flow measured by the blood flow measurement unit 13. Is calculated. Also, the blood flow wave height graph tends to be more similar to the shape of the amylase concentration graph than the blood flow rate graph. Therefore, the relationship between the state of the autonomic nerve and the blood flow is calculated more accurately by measuring the blood flow wave height. The relationship between the state of the autonomic nerve and the blood flow calculated by the control unit 11 is stored in the storage unit 14. The relationship between the state of the autonomic nerve and the blood flow is not limited to the relationship in which the activity of the sympathetic nerve increases (decreases) when the blood flow increases (decreases). Examples of the relationship between the state of other autonomic nerves and blood flow are as follows.
・ When the blood flow wave height is 10 [ml / min] or more, the subject is stimulated. ・ When the blood flow wave height is less than 10 [ml / min], the subject is resting without stimulation. When the flow wave height is 12 [ml / min], the activity of the exchange nerve increases.

  The control unit 11 calculates the state of the autonomic nerve based on the measured blood flow and the relationship between the state of the autonomic nerve and the blood flow stored in the storage unit 14. The control unit 11 transmits the calculated state of the autonomic nerve to the terminal device 2 as the state information of the autonomic nerve. The terminal control unit 21 of the terminal device 2 causes the display unit 22 to display autonomic nerve state information. The state information of the autonomic nerve is, for example, whether or not the target is stimulated, whether the activity of the sympathetic nerve is high or low, and the like.

  FIG. 7 is a diagram showing a graph when the blood flow wave height and amylase concentration of another subject whose blood pressure is higher than the subject whose blood flow and amylase were measured in FIG. 6 are measured. As shown in FIG. 7, both the blood wave height and the amylase concentration peak at time t12. In FIG. 6, the peak of amylase concentration is 6 minutes behind the peak of blood flow wave height, but in FIG. 7, the peak of amylase concentration is simultaneous with the peak of blood flow wave height. That is, the higher the blood pressure of the target, the shorter the time required from when the stimulus is actually felt until it is reflected in the amylase concentration.

  As described above, the blood flow measurement device 1 first associates the blood flow with amylase and stores the relationship between the blood flow and the state of the autonomic nerve in the storage unit 14. From the next time, the blood flow measuring device 1 can calculate the state of the autonomic nerve based on the relationship and the blood flow measured by the blood flow measuring unit 13. At this time, since the measurement of the amylase concentration is unnecessary, the blood flow measuring device 1 can measure the state of the autonomic nerve.

  For example, the blood flow measurement unit 13 of the blood flow measurement device 1 measures blood flow for a predetermined time (for example, 10 minutes) based on an operation by the object. The control unit 11 calculates the state of the autonomic nerve based on the measured blood flow and the relationship between the state of the autonomic nerve and the blood flow stored in the storage unit 14. When calculating the state of the autonomic nerve, the control unit 11 outputs the state information of the autonomic nerve to the terminal device 2. The display unit 22 of the terminal device 2 displays the state information of the autonomic nerve.

  The calculation system S according to the present embodiment is used, for example, to determine whether or not the subject has relaxed (feels comfortable) by measuring the blood flow in a resting state before and after the massage. Can do. Further, the calculation system S according to the present embodiment can calculate an index of chronic depression by calculating the state of the autonomic nerve over a period of several days or the like.

  A method for calculating the state of the autonomic nerve executed by the calculation system S according to the present embodiment will be described with reference to the flowchart shown in FIG.

  After the blood flow measurement device 1 is attached to the subject, the blood flow measurement device 1 starts measuring blood flow based on an operation by the subject (step S1). Whether the blood flow volume or the blood flow wave height is measured is arbitrary. The blood flow measurement device 1 determines whether or not a predetermined time (eg, 10 minutes) has elapsed since the start of blood flow measurement (step S2), and if the predetermined time has elapsed (step S2). Yes), the terminal device 2 is notified that the predetermined time has passed (step S3). The terminal device 2 that has received the notification notifies the amylase measuring device 3 that a predetermined time has elapsed (step S4).

  After step S2, the blood flow measuring device 1 continues to measure blood flow (step S5). The terminal device 2 performs a test for a predetermined time (for example, 10 minutes) (step S6). Since the specific example of the test is as described above, the description is omitted. The subject then takes the test. At the same time, the amylase measuring apparatus 3 measures the amylase concentration in saliva at a predetermined time (eg, 20 minutes) and at a predetermined interval (eg, 2 minutes) based on the saliva collection operation by the subject (step S7).

  When the measurement of the amylase concentration is completed, the amylase measurement device 3 transmits the amylase concentration as a measurement result to the blood flow measurement device 1 via the terminal device 2 (step S8 and step S9).

  The blood flow measurement device 1 that has received the measurement result associates the measured blood flow with the measured amylase concentration (step S10). For example, the blood flow measurement device 1 performs association by matching the measured blood flow volume or blood flow wave peak with the measured amylase concentration peak. As a result, the blood flow measurement device 1 calculates the relationship between the state of the autonomic nerve and the blood flow.

  The blood flow measurement device 1 stores the calculated relationship between the autonomic nerve state and the blood flow in the storage unit 14 (step S11). The blood flow measurement device 1 calculates the state of the autonomic nerve based on the stimulus received by the subject based on the relationship stored in step S11 and the blood flow measured in step S1 (step S12).

  The blood flow measuring device 1 transmits the calculated state of the autonomic nerve to the terminal device 2 as the state information of the autonomic nerve (step S13). The terminal device 2 displays the state information of the autonomic nerve on the display unit 22 (step S14). As described above, the blood flow measurement device 1 calculates the relationship between the state of the autonomic nerve and the blood flow, and stores it in the storage unit 14. Therefore, the blood flow measuring device 1 can calculate the state of the autonomic nerve based on the blood flow without measuring the amylase concentration when measuring the blood flow at the next opportunity as follows.

  After being attached to the subject, the blood flow measuring device 1 measures the blood flow of the subject for a predetermined time (eg, 10 minutes) based on an operation by the subject (step S21).

  When the blood flow measurement is completed, the blood flow measurement device 1 calculates the state of the target autonomic nerve based on the relationship stored in step S10 (step S22). The blood flow measuring device 1 transmits the calculated state of the autonomic nerve to the terminal device 2 as the state information of the autonomic nerve (step S23). The terminal device 2 displays the state information of the autonomic nerve on the display unit 22 (step S24).

  As described above, the blood flow measurement device 1 according to the present embodiment stores the storage unit 14 that stores the relationship between the state of the autonomic nerve and the blood flow, the blood flow measurement unit 13 that measures the blood flow, and the like. A control unit 11 that calculates the state of the autonomic nerve based on the relationship and the measured blood flow is provided. The blood flow measurement device 1 of the present embodiment can non-invasively measure blood flow. Therefore, the blood flow measurement device 1 of the present embodiment can measure the state of the autonomic nerve.

  Moreover, the blood flow measurement device 1 of the present embodiment is based on the relationship between the state of the autonomic nerve and the blood flow based on the relationship between the target amylase measured when the target is stimulated and the measured blood flow. To calculate. In general, it is known that the amylase concentration in saliva reflects the activity of the sympathetic nervous system. For this reason, if the relationship between the state of the autonomic nerve and the blood flow is calculated based on the relationship between the amylase and the blood flow, the state of the autonomic nerve can be calculated more accurately by measuring the blood flow.

  According to the present embodiment, the calculation system S includes the amylase measuring unit 31 that measures the target amylase when the stimulus is given to the target, and the blood flow measuring unit 13 that measures the blood flow. The calculation system S further includes a control unit 11 that calculates the relationship between the state of the autonomic nerve and the blood flow based on the relationship between the measured amylase and the measured blood flow. For this reason, the calculation system S can calculate the state of the autonomic nerve by measuring the blood flow using the measured amylase concentration. Therefore, the calculation system S can visualize the state of the autonomic nerve.

  In addition, the blood flow measurement unit 13 of the present embodiment measures the blood flow of the subject from a predetermined time before the time when the stimulus starts to be applied to the subject. In general, the response of amylase concentration to a stimulus takes one to several minutes. Therefore, the blood flow measurement unit 13 of the present embodiment can associate the concentration of amylase collected during giving a stimulus with the blood flow before starting to give the stimulus.

  In addition, the control unit 11 of the present embodiment performs association by matching the measured peak of amylase concentration with the measured blood flow volume or blood flow wave peak. By matching the peaks, the shape of the graph of blood flow volume or blood flow wave height substantially matches the shape of the graph of amylase concentration. Therefore, the blood flow measurement device 1 of the present embodiment improves the reliability of calculating the state of the autonomic nerve based on the blood flow volume or blood flow wave height measurement value.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, functions included in each member, each part, each step, and the like can be rearranged so as not to be logically contradictory. Also, when the present invention is implemented as a method invention, it is possible to combine or divide a plurality of parts or steps into one.

  In the said embodiment, the display part 22 of the terminal device 2 displays the state information of an autonomic nerve. As for the display part 22 of the terminal device 2, the blood-flow measuring device 1 may be provided with a display part, and may display the state information of an autonomic nerve. As an alternative example, the blood flow measurement device 1 may include an audio output unit to reproduce the state information of the autonomic nerve as audio. Moreover, the blood flow measurement device 1 may include an input unit for receiving an input operation (for example, an instruction to start blood flow measurement and autonomic nerve state calculation) by a target. If comprised in this way, the object can know the state of its own autonomic nerve, without connecting the blood flow measuring device 1 and the terminal device 2.

  In the above embodiment, the subject operates the amylase measuring device 3 at least once to measure its own amylase concentration. However, if the relationship between the blood flow and the state of the autonomic nerve is statistically calculated (for example, for each test type, for each sex, for each age, etc.) and stored in the storage unit 14, the subject measures the amylase concentration once. Without knowing, it is possible to know the state of the autonomic nerve based on the measured blood flow.

  Moreover, in the said embodiment, the blood flow measuring apparatus 1 performs the correlation of a blood flow and the state of an autonomic nerve, and the calculation of the state of an autonomic nerve. However, the terminal device 2 may execute these processes.

  Moreover, in the said embodiment, the terminal device 2 starts a test 10 minutes after the blood flow measuring device 1 starts measuring a blood flow. However, the terminal device 2 may start the test immediately after the start of the measurement. The terminal device 2 may start the test at any timing of 1 minute, 2 minutes, 3 minutes,...

  Moreover, in the said embodiment, it demonstrated that the control part 11 with which the blood-flow measuring device 1 is provided produces | generates biometric information based on the biometric output which the transmissive | pervious sensor 12 or the reflective sensor 13 acquired. The generation of the biological information is not limited to the case where the control unit 11 included in the blood flow measurement device 1 performs. For example, the blood flow measurement device 1 and a server device connected via a wired or wireless network or a combination thereof may include a functional unit corresponding to the control unit 11 and generate biological information. In this case, the blood flow measurement device 1 transmits the biological measurement output acquired by the transmission sensor 12 or the reflection sensor 13 from the communication unit 15 to the server device. The server device calculates biometric information based on the biometric information output, and stores the calculated biometric information in the storage unit. As described above, when the server device calculates the biological information and stores the biological information, the blood flow measuring device 1 can be compared with the case where all the functional units shown in FIG. Miniaturization and the like can be realized.

DESCRIPTION OF SYMBOLS 1 Blood flow measuring device 11 Control part 12 Transmission type sensor 12a Light emission part 12b Light receiving part 13 Reflection type sensor (blood flow measurement part)
13a Light emitting unit 13b Light receiving unit 14 Storage unit 15 Communication unit 2 Terminal device 21 Terminal control unit 22 Display unit 23 Input unit 24 Communication unit 3 Amylase measuring device 31 Amylase measuring unit

Claims (14)

A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow wave height;
A light receiving unit that receives scattered light from the test site;
A blood flow measurement unit for measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
A control unit that calculates the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
A blood flow measurement device comprising: The blood flow wave height, Ru Sadea between the maximum value and the minimum value of the blood flow rate per heartbeat one heartbeat, blood flow measuring apparatus according to claim 1. A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow;
A blood flow measurement unit for measuring blood flow;
A controller that calculates the state of the autonomic nerve based on the stored relationship and the measured blood flow,
The relationship between the state of the autonomic nerve and the blood flow is calculated based on the relationship between the target amylase measured when a stimulus is applied to the target and the measured blood flow. . A storage unit for storing the relationship between the state of the autonomic nerve and the blood flow wave height;
A light receiving unit that receives scattered light from the test site;
A blood flow measurement unit for measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
A control unit that calculates the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
A calculation system comprising: The blood flow wave height, Ru Sadea between the maximum value and the minimum value of the blood flow rate per heartbeat one heartbeat, calculation system of claim 4. An amylase measuring unit for measuring the amylase of the subject when the subject is stimulated;
A blood flow measurement unit for measuring blood flow;
Based on the relationship between the measured amylase and the measured blood flow, a control unit that calculates the relationship between the state of the autonomic nerve and the blood flow,
A calculation system comprising: The blood flow measurement unit measures the blood flow of the subject from a predetermined time before the time when the subject begins to be stimulated,
The calculation system according to claim 6, wherein the control unit calculates a relationship between the state of the autonomic nerve and the blood flow by associating the measured blood flow with the measured amylase.   The said control part performs the said correlation by matching the peak of the measured density | concentration of amylase, and at least one peak of the measured blood flow volume and blood flow wave height. Calculation system. Memorizing the relationship between the state of the autonomic nerve and the blood flow wave height;
Receiving scattered light from the test site;
Measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
Calculating the state of the target autonomic nerve based on the stored relationship and the blood flow wave height of the target;
A blood flow measurement method comprising: The blood flow wave height, Ru Sadea between the maximum value and the minimum value of the blood flow rate per heartbeat one heartbeat, blood flow measuring method according to claim 9. Memorizing the relationship between the state of the autonomic nerve and blood flow;
Measuring blood flow;
Calculating an autonomic state based on the stored relationship and the measured blood flow,
The relationship between the state of the autonomic nerve and the blood flow is a blood flow measurement method, which is a relationship between the amylase of the target measured when a stimulus is given to the target and the measured blood flow. On the computer,
Receiving scattered light from the test site;
Measuring a blood flow height from a blood flow measured based on a Doppler shift of the frequency of the scattered light received ;
Calculating the state of the autonomic nerve based on the blood flow wave height and the relationship between the state of the autonomic nerve stored in the storage unit and the blood wave wave height;
A blood flow measurement program. The blood flow wave height, Ru Sadea between the maximum value and the minimum value of the blood flow rate per heartbeat one heartbeat, blood flow measuring program according to claim 12. On the computer,
Measuring blood flow;
Based on the blood flow and the relationship between the target amylase and the measured blood flow measured when a stimulus is applied to the object stored in the storage unit, the state of the target autonomic nerve is determined. A calculating step;
A blood flow measurement program.

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