JP2004141281A - Instrument and method for circulatory kinetics measurement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an instrument and a method for circulatory kinetics measurement which realize easy determination of the risk factor of a disease concerning a circulatory system when applied to determine the risk factor of the circulatory system especially cerebral infarction, or the like. <P>SOLUTION: The instrument determines a change in a blood pressure value and a change in a pulse value before and after changing a posture to determine the risk factor of cerebral infarction, or the like. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a circulatory dynamics measuring device and a circulatory dynamics measuring method, and can be particularly applied to measurement of a disease risk factor in a circulatory system such as cerebral infarction. The present invention makes it possible to easily determine a risk factor of a disease relating to a circulatory system by determining a change amount of a blood pressure value and a change amount of a pulse value before and after changing a posture.
[0002]
[Prior art]
Today, inexpensive electronic sphygmomanometers, pulse meters, body fat meters, and the like that can be measured quickly and inexpensively are provided as health management devices, and are used to prevent various diseases.
[0003]
Among these health care devices, an electronic sphygmomanometer, which is a circulatory activity measuring device, is useful for preventing cerebral infarction, myocardial infarction and the like, which are diseases in which hypertension is a risk factor. That is, in the user, the systolic blood pressure and the diastolic blood pressure measured by the electronic sphygmomanometer are determined by, for example, blood pressure classification of WHO (World Health Organization) to determine hypertension or the like, or these systolic blood pressure and diastolic blood pressure were measured before. It is determined whether the blood pressure value is abnormally changed and used for health management.
[0004]
In such an electronic sphygmomanometer, in order to measure quickly and accurately, it is required that the human body be kept still and the load on the heart be kept constant during the measurement. On the other hand, at present, some hospitals adopt a method in which a tilt table is tilted to change the posture of a sleeping patient, and a blood pressure change before and after the posture is input to test a nerve regulation function. .
[0005]
Japanese Patent Application Laid-Open No. 2002-136486 proposes a method of processing the measurement result of such a sphygmomanometer and evaluating the degree of arteriosclerosis.
[0006]
[Patent Document 1]
JP 2002-136486 A
[0007]
[Problems to be solved by the invention]
By the way, cerebral infarction, which is one of the diseases related to the circulatory system, has a high tendency to develop due to high blood pressure. By the way, cerebral infarction that develops with normotensive blood pressure is sometimes called asymptomatic cerebral infarction.
[0008]
If it is possible to measure the risk factor of diseases related to the circulatory system such as cerebral infarction by this, it is thought that it can be further useful for health management, whereas the conventional circulatory dynamic measurement device is A risk factor cannot be determined, and there has been a long-awaited commercialization of a circulatory dynamics measuring instrument for measuring such a risk factor.
[0009]
Today, with respect to blood pressure measurement, a technology has been established, and if the technology of blood pressure measurement can be used to measure such a risk factor, a circulatory dynamic measurement device that can quickly and accurately determine a risk factor can be provided. Conceivable.
[0010]
The present invention has been made in view of the above points, and an object of the present invention is to propose a circulatory dynamics measurement and a circulatory dynamics measuring method that can easily determine a risk factor of a disease relating to a circulatory system.
[0011]
[Means for Solving the Problems]
In order to solve this problem, the present invention is applied to a circulatory dynamics measuring device, and processes a blood pressure measuring means, a pulse measuring means, and a blood pressure value by the blood pressure measuring means and a pulse value by the pulse measuring means. Data processing means, wherein the data processing means calculates a change amount of the blood pressure value and a change amount of the pulse value before and after the subject changes posture, and calculates a change amount of the blood pressure value and the pulse value. The risk factor of a disease relating to the circulatory system is determined from the amount of change, and the determination result is reported.
[0012]
In the second aspect of the present invention, in the circulatory dynamic measurement device according to the first aspect, the change amount of the blood pressure value is a change amount of the systolic blood pressure value, and the risk factor of the disease relating to the circulatory system is cerebral infarction. In the two-dimensional coordinate space of the coordinate axes corresponding to the change amount of the blood pressure value and the change amount of the pulse value, the data processing unit calculates the change amount of the blood pressure value and the change amount of the pulse value. The risk factor is determined based on the position of the coordinates.
[0013]
According to a third aspect of the present invention, in the circulatory dynamic measurement device according to the first aspect, the change amount of the blood pressure value is a change amount of the pulse pressure, and the risk factor of the disease related to the circulatory system is cerebral infarction. A risk factor, wherein the data processing means is configured to determine, in a two-dimensional coordinate space for determination by a determination reference axis corresponding to the change amount of the pulse pressure and the change amount of the pulse value, the change amount of the pulse pressure and the pulse value The risk factor is determined based on the quadrant of the coordinates based on the amount of change.
[0014]
Further, in the invention according to claim 4, a first information acquisition step of applying a blood pressure value and a pulse value before the posture change of the subject by applying to the circulatory dynamic measurement method, and a blood pressure value after the posture change of the subject Information acquisition step for acquiring the blood pressure value and the pulse value, and a change in the blood pressure value for calculating an amount of change between the blood pressure value acquired in the first information acquisition step and the blood pressure value acquired in the second information acquisition step An amount calculating step, a pulse value change amount calculating step of calculating a change amount between the pulse value obtained in the first information obtaining step and the pulse value obtained in the second information obtaining step, and a change in the blood pressure value. A risk factor determining step of determining a cerebral infarction risk factor from the change amount calculated in the amount calculating step and the pulse value change amount calculating step.
[0015]
When the subject changes his or her posture, the blood pressure value temporarily fluctuates with the change in the posture, and after a few minutes, the blood pressure value almost returns to the blood pressure value before the posture change. Similarly, when the posture is changed, the pulse value changes in response to the increase in blood pressure accompanying the change in posture, and after a few minutes, the pulse value almost returns to the pulse value before the posture change. On the other hand, when the blood pressure value and the pulse value change excessively with respect to the posture change, and when the change in the pulse value does not correspond to the change in the blood pressure value, the neural adjustment is performed normally even if the blood pressure value is normal. It was found that this was a case where it did not function and the burden on the circulatory system was large, and especially the risk factor for cerebral infarction was high.
[0016]
Thus, according to the configuration of claim 1, the change amount of the blood pressure value and the change amount of the pulse value before and after the subject changes the posture are calculated, and the change amount of the blood pressure value and the change amount of the pulse value are calculated. By determining the risk factor related to the circulatory system from the above and reporting the determination result, the risk factor of the disease related to the circulatory system can be determined easily and quickly.
[0017]
According to the configuration of claim 2, in the circulatory dynamic measurement device according to claim 1, the change amount of the blood pressure value is a change amount of the systolic blood pressure value, and the risk factor related to the circulatory system is cerebral infarction. A risk factor, wherein the data processing means is a two-dimensional coordinate space based on coordinate axes corresponding to the change amount of the blood pressure value and the change amount of the pulse value, and the coordinate based on the change amount of the blood pressure value and the change amount of the pulse value. The risk factor of cerebral infarction among the risk factors of diseases relating to the circulatory system can be easily and quickly determined by determining the risk factor based on the position of the circulatory system.
[0018]
According to the third aspect of the present invention, in the circulatory dynamic measurement device according to the first aspect, the change in the blood pressure value is a change in the pulse pressure, and the risk factor of the disease relating to the circulatory system is cerebral infarction. In the two-dimensional coordinate space for determination by the determination reference axis corresponding to the change amount of the pulse pressure and the change amount of the pulse value, the data processing means The risk factor of cerebral infarction can be determined from the quadrant by determining the risk factor from the quadrant of the coordinates based on the amount of change in the value.
[0019]
Further, according to the configuration of the fourth aspect, the first information acquiring step of acquiring the blood pressure value and the pulse value before the subject's posture change, and the second information acquiring step of acquiring the blood pressure value and the pulse value after the subject's posture change. A second information obtaining step; a blood pressure value change amount calculating step of calculating a change amount between the blood pressure value obtained in the first information obtaining step and the blood pressure value obtained in the second information obtaining step; A pulse value change amount calculating step of calculating a change amount between the pulse value obtained in the information obtaining step and the pulse value obtained in the second information obtaining step; the blood pressure value change amount calculating step and the pulse value change A risk factor determining step of determining a cerebral infarction risk factor from the amount of change calculated in the amount calculating step. Can.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
[0021]
(1) First embodiment
(1-1) Configuration of First Embodiment
FIG. 2 is a block diagram showing a circulatory dynamics measuring device according to the first embodiment of the present invention. The circulatory dynamic measurement device 1 determines a risk factor for cerebral infarction, which is one of the diseases of the circulatory system, from the blood pressure value and the pulse value, and notifies the user of the determination result. The circulatory activity measuring device 1 is configured such that a cuff 2 wound around an upper arm or the like of a subject is connected to a circulatory activity measuring device main body 3 by an air tube (not shown).
[0022]
In the configuration of the circulatory dynamic measurement device 1, the configuration related to the measurement of blood pressure and pulse is the same as that of the existing oscillometric blood pressure monitor, whereby the circulatory dynamic measurement device 1 measures the measured blood pressure value and pulse value. It is displayed so that it can be used as a normal electronic sphygmomanometer. For this reason, in the circulatory dynamics measuring device 1, the cuff 2, the pump 5, the exhaust valve 7, and the pressure sensor 8 together with the control unit 6 constitute a blood pressure measuring means and a pulse measuring means.
[0023]
In the main body 3 of the circulatory dynamics measuring device 1, the power supply 4 is composed of a dry cell or an AC adapter, and supplies power for operation to the controller 6, the liquid crystal display 12, the pump 5, and the like.
[0024]
The posture switch 14 is a pressing operator that receives an input of the posture of the subject. In the present embodiment, symbols representing postures (seated position, recumbent position, standing position, etc.) are displayed on the liquid crystal display unit 12, and the posture switch 14 is selected by operating these posture switches 14 according to voice instructions. The input of the posture of the subject is received in accordance with the operation direction (e.g., a sitting position on the back side and a standing position on the near side). Thereby, in the circulatory dynamics measuring device 1, the posture of the subject is specified by the operation of the posture switch 14 by the subject himself, and the overall configuration is compared with a case where the posture is detected using, for example, an acceleration sensor or the like. Can be simplified.
[0025]
The changeover switch 11 is an operator for switching the operation of the circulatory dynamics measuring device 1 between a normal electronic sphygmomanometer and a risk factor measuring device. In the circulatory dynamics measuring device 1, the operation of the changeover switch 11 stops the display of the blood pressure value or the like on the liquid crystal display unit 12 and waits for the operation of the posture switch 14.
[0026]
The start switch 10 is an operator for instructing the start of the measurement. In the measurement of the risk factor, the operation is accepted after the posture switch 14 is operated and the posture of the subject is specified.
[0027]
The control unit 6 is a computer that controls the entire operation of the circulatory dynamic measurement device 1. In addition to the configuration related to the sphygmomanometer, a processing program for determining and notifying a risk factor, a criterion necessary for executing the processing program The value is held. Note that these processing programs, determination reference values, and the like are recorded when the circulatory dynamics measuring device 1 is manufactured.
[0028]
That is, FIG. 1 is a flowchart for explaining a processing program used for determination and notification of the risk factor. When a power switch (not shown) is operated, the control unit 6 starts operation by supplying power from the power supply 4, and starts the processing program when the subject instructs to measure a risk factor by operating the changeover switch 11. I do.
[0029]
In this processing program, in this processing program, when the start switch 10 is operated after the posture switch 14 is operated by the subject, the process proceeds from step SP1 to step SP2, and the posture specified by the operation of the posture switch 14 is Measure blood pressure and pulse. In the control unit 6, in the measurement of the blood pressure and the pulse, the blood flow is stopped by operating the pump 5 to inflate the cuff 2 in the same manner as in the normal blood pressure monitor. 7 is opened and the systolic blood pressure, the diastolic blood pressure, and the pulse are calculated by processing the output signal of the pressure sensor 8 and stored in a memory (not shown). Thus, the control unit 6 measures the systolic blood pressure, the diastolic blood pressure, and the pulse in the sitting position before the posture change.
[0030]
Subsequently, the control unit 6 proceeds to step SP3, and outputs, for example, a message "Please stand" by voice and / or displays it on the liquid crystal display unit 12, thereby prompting the subject to stand up.
[0031]
Subsequently, the control unit 6 proceeds to step SP4, waits for the operation of the posture switch 14, and when the subject operates the posture switch 14, proceeds to step SP5. Measure blood pressure and pulse. Thereby, the control unit 6 measures the systolic blood pressure, the diastolic blood pressure, and the pulse in the standing position after the posture change.
[0032]
Subsequently, the control unit 6 proceeds to step SP6, subtracts the systolic blood pressure value after standing from the systolic blood pressure value before standing from the measurement results measured in step SP2 and step SP6, and calculates the change amount as the change amount ΔPP of the blood pressure. Is calculated as In the subsequent step SP7, similarly, the pulse value after standing up is subtracted from the pulse value before standing up, and the change amount ΔHR of the pulse is calculated.
[0033]
Subsequently, the control unit 6 proceeds to step SP8, and determines a risk factor for cerebral infarction from the blood pressure change amount ΔPP and the pulse change amount ΔHR calculated in this manner.
[0034]
This determination is made, as shown in FIG. 3, in a two-dimensional coordinate space in which the change amount of pulse ΔHR and the change amount of systolic blood pressure ΔPP are set on the horizontal axis and the vertical axis, respectively. It is performed by the position of the coordinates by the quantity ΔHR. In addition, such a determination method is based on the content published by the inventor, Mr. Kario, as a research result based on medical empirical rules.
[0035]
Specifically, the control unit 6 determines that the risk factor for cerebral infarction is normal, in other words, when the change amount of blood pressure ΔPP and the change amount of pulse ΔHR belong to the range of plus 20 to 30 and plus 20 to minus 20, respectively. The risk of cerebral infarction is determined to be low. On the other hand, when the change amount ΔPP of the blood pressure belongs to the area AR1 on the side larger than the first determination reference value TH1, which is plus 20, it is determined that the risk of cerebral infarction is large. Similarly, when the change amount ΔPP of the blood pressure is smaller than the second determination reference value TH2 of −20 and the change amount ΔHR of the pulse is distributed in an area AR2 smaller than the third determination reference value TH3 of plus 20, It is determined that the risk of cerebral infarction is great. Similarly, when the blood pressure change amount ΔPP is between the first determination reference value TH1 and the second determination reference value TH2 and the pulse change amount ΔHR belongs to an area AR3 larger than the third determination reference value TH3, If the change in hypertension is not excessive, but the pulse is significantly increased, it is determined that the risk of cerebral infarction is high.
[0036]
Further, when the blood pressure change amount ΔPP is smaller than the second determination reference value TH2 and the pulse change amount ΔHR belongs to an area AR4 larger than the third determination reference value TH3, in other words, If the systolic blood pressure of the patient is excessively decreased and the pulse after standing is significantly increased, the risk factor for orthostatic hypotension is large, and it is determined that there is a risk of falling.
[0037]
These criteria are based on clinical data obtained by actually measuring the onset and non-onset of cerebral infarction, and the data of these criteria are stored in the control unit 6 in advance. In addition, among the divisions based on these determination reference values TH1 to TH3, an area AR1 that is equal to or greater than the determination reference value TH1 and an area AR2 that is equal to or less than the determination reference value TH2 generally include subjects with orthostatic hypertension and orthostatic hypotension, respectively. The region AR4 that is equal to or greater than the determination reference value TH3 is a region to which a subject with orthostatic tachycardia mainly belongs.
[0038]
When the risk factor for cerebral infarction and the risk factor for orthostatic hypotension are determined in this way, the control unit 6 proceeds from step SP8 to step SP9, and displays the determination results on the liquid crystal display unit 12 together with the blood pressure and pulse measurement results. I do. More specifically, the control unit 6 displays the systolic blood pressure, the diastolic blood pressure, and the pulse before standing up on the liquid crystal display unit 12 using numbers. When a determination result that the risk factor of cerebral infarction is high is obtained, a message indicating that caution is required for cerebral infarction is displayed. If a determination result that the risk factor for orthostatic hypotension is large is obtained, a message of “beware of darkness and falling” is displayed.
[0039]
When displaying this message, the control section 6 moves from step SP9 to step SP10 and ends this processing procedure.
[0040]
As shown in FIG. 4 by these functional block diagrams, in the circulatory dynamics measuring device 1, the cuff 2, the pump 5, the exhaust valve 7, the pressure sensor 8, and the control unit 6 constitute a blood pressure measuring means and a pulse measuring means. The control section 6 constitutes a data processing means for processing the blood pressure value and the pulse value measured by the blood pressure measuring means and the pulse measuring means.
[0041]
(1-2) Operation of First Embodiment
In the above configuration, after the cuff 2 is mounted on the upper arm, the entire operation of the circulatory dynamic measurement device 1 is switched so that the risk factor is measured by operating the changeover switch 11 when the user sits down on the chair and settles down. Thereafter, the posture of the subject is input by operating the posture switch 14. Subsequently, by pressing the start switch 10, the blood pressure and the pulse before the posture change in the sitting position are measured. That is, in the circulatory dynamics measuring device 1, air is sent into the cuff 2 by the pump 5, and the blood flow is stopped. Thereafter, the exhaust valve 7 is opened, and the output signal of the pressure sensor 8 is processed by the control unit 6 while the air in the cuff 2 is exhausted. Thus, the control unit 6 detects the systolic blood pressure, the diastolic blood pressure, and the pulse, and stores these values.
[0042]
Next, the subject is instructed to stand up, and the subject stands up and operates the posture switch 14 to input the changed posture. When the start switch 10 is subsequently pressed, the systolic blood pressure, the diastolic blood pressure, and the pulse are measured in the same manner as before the posture change, and these values are stored.
[0043]
In the circulatory dynamic measurement device 1, these measurement results are processed by the control unit 6, and the blood pressure change ΔPP and the corresponding pulse change ΔHR are calculated, and the blood pressure change ΔPP and the corresponding pulse change are calculated. By determining the amount ΔHR, a risk factor for cerebral infarction is determined.
[0044]
That is, when the posture of the subject changes, such as when standing up from a seated state, the load on the circulatory system temporarily increases due to the movement due to the change in the posture. In a normal reaction by a healthy human body to such a temporary increase in the load, the blood pressure value temporarily changes due to a change in posture, and returns to the blood pressure value almost before the change in posture after several minutes. In addition, the pulse value changes in response to an increase in the blood pressure value due to a change in posture so as to correspond to such a reaction of blood pressure, and returns to the pulse value almost before the change in posture after several minutes.
[0045]
On the other hand, when the risk factors for various diseases related to the circulatory system such as cerebral infarction, stroke, subarachnoid hemorrhage, etc. are large, unlike normal reactions by such a healthy human body, neuromodulation is normal. As in the case where the blood pressure does not function, a state in which the blood pressure value or the pulse excessively changes due to the change in the state, or a state in which the change in the pulse does not correspond to the change in the blood pressure value is observed.
[0046]
Thus, the circulatory dynamic measurement device 1 can be used as a sphygmomanometer and a sphygmomanometer as well as determine the risk of cerebral infarction or the like from the change in blood pressure and the change in pulse.
[0047]
The circulatory dynamic measurement device 1 specifies the amount of change in the blood pressure value and the amount of change in the pulse value on the corresponding two-dimensional coordinate planes, and such a risk is determined based on the specified places.
[0048]
That is, when the change amount of the blood pressure value belongs to the area AR1 equal to or larger than the predetermined determination reference value TH1, it is determined that the risk factor for cerebral infarction is large. Also, when the change amount of the blood pressure value is equal to or less than the predetermined determination reference value TH2 and the change amount of the pulse value belongs to the area AR2 equal to or less than the determination reference value TH3, it is determined that the risk factor for cerebral infarction is large. Also, when the change amount of the pulse value is between these determination reference values TH1 and TH2 and the change amount of the pulse value belongs to the area AR3 that is equal to or more than the determination reference value TH3, it is determined that the risk factor for cerebral infarction is large. . Thus, the circulatory dynamic measurement device 1 determines the change amounts of the blood pressure value and the pulse value using the determination reference values TH1, TH2, and TH3, respectively, and easily determines the risk factor of cerebral infarction by performing a logical operation on each determination result. can do.
[0049]
If the change amount of the blood pressure value is equal to or smaller than the predetermined determination reference value TH2 and the change amount of the pulse value belongs to the area AR4 equal to or larger than the determination reference value TH3, it is determined that the risk factor for orthostatic hypotension is large. Thus, diseases other than cerebral infarction can be easily determined together. In the age when such a cerebral infarction is a problem, the occurrence of secondary damage such as a fracture due to a fall is a problem in orthostatic hypotension.
[0050]
The circulatory dynamic measurement device 1 notifies the subject of the risk of cerebral infarction thus obtained alone or together with the blood pressure value and the pulse value, and uses it for the health management of the subject. The measured values recorded in the memory will be confirmed at a later date and used for health management.
[0051]
(1-3) Effects of the first embodiment
According to the above configuration, the amount of change in the blood pressure value and the amount of change in the pulse value before and after the posture change between the sitting position and the standing position are calculated, and these are determined in light of the determination criterion. It is possible to easily and reliably determine the risk factor of a disease relating to the organ system. Thereby, such a risk factor can be detected in advance and used for avoiding a disease.
[0052]
In addition, by using existing blood pressure monitor technology, blood pressure value, pulse value is measured, and the amount of change in these blood pressure value and pulse value is specified on a two-dimensional coordinate plane to determine a risk factor for cerebral infarction, The risk of cerebral infarction or the like can be known without using an expensive device or a complicated measurement method.
[0053]
(2) Second embodiment
In this embodiment, as shown in FIG. 5, the determination reference axes LX and LY corresponding to the change amount of the pulse pressure (the difference between the systolic blood pressure and the diastolic blood pressure) and the change amount of the pulse value before and after the posture change. In the two-dimensional coordinate space for the determination by, the risk factor such as cerebral infarction is determined from the quadrant of the coordinates based on the amount of change in pulse pressure and the amount of change in pulse value. In this embodiment, the same configuration as that of the first embodiment is the same as that of the first embodiment except that the processing related to this determination is different. Is omitted.
[0054]
The amount of change in pulse pressure and the amount of change in pulse value are actually measured in patients with and without cerebral infarction, and the amount of change in pulse pressure and the amount of change in pulse value are set on the Y-axis LY and the X-axis LX, respectively. Plotted in the two-dimensional coordinate space, the change in the pulse pressure and the pulse value is larger than the predetermined values THY and THX, respectively, and conversely, the change in the pulse pressure and the pulse value are the predetermined values THY and THX, respectively. If smaller, the risk of cerebral infarction was found to be high. Here, the predetermined values THY and THX are a change in pulse pressure of 20 [mmHg] and a change in pulse value of 25 [ppm].
[0055]
It was also found that the greater the distance from the origin by the determination reference axis or the greater the distance from the determination reference axis, the higher the danger.
[0056]
Accordingly, a two-dimensional coordinate space for determination based on the determination reference axes, which are the predetermined values THY and THX, is set for the coordinate space based on the change amount of the pulse pressure and the change amount of the pulse value. If the measurement result is located in the first quadrant or the third quadrant in the two-dimensional coordinate space, it can be determined that the risk of cerebral infarction is high. Further, the degree of danger can be detected by digitizing the distance from the origin or the determination coordinate axis.
[0057]
Therefore, in the circulatory dynamic measurement device according to the present embodiment, the control unit calculates the pulse pressure by subtracting the diastolic blood pressure value from the systolic blood pressure value before and after the posture change. Further, the pulse pressure value after the posture change is subtracted from the pulse pressure value before the posture change with respect to the pulse pressure value calculated in this way, and thereby the amount of change in the pulse pressure value is calculated. Further, the amount of change in the pulse is calculated by the same processing as in the first embodiment.
[0058]
Further, the change amount of the pulse pressure value and the change amount of the pulse calculated as described above are determined by the determination reference values THY and THX, respectively, and thereby, the quadrant in the two-dimensional coordinate space for determination is detected.
[0059]
Further, the distance from each coordinate axis is calculated by subtracting the change amount of the pulse pressure value and the change amount of the pulse from these determination reference values THY and THX, and the risk is quantified by selecting the distance with the smaller value. I do. In this case, the risk may be quantified by adding the distances from the respective coordinate axes, or by adding the squares of the distances from the respective coordinate axes.
[0060]
After calculating the risk in this way, the control unit notifies the subject of the calculation result.
[0061]
According to the second embodiment, in the two-dimensional coordinate space for determination by the determination reference axis corresponding to the change amount of the pulse pressure and the change amount of the pulse value, the change amount of the pulse pressure and the change amount of the pulse value By determining the risk factor based on the quadrant of the coordinates, the risk factor for cerebral infarction can be accurately determined by a simple process of determining the sign in the two-dimensional coordinate space for this determination.
[0062]
(3) Other embodiments
In the above-described first embodiment, the case where the magnitude of danger is simply determined and notified is described. However, the present invention is not limited to this, and is quantified as in the second embodiment. The risk factor may be reported. In addition, such a numerical value can be represented by a distance from a normal region. In addition to the numerical value of the risk factor, in addition to reporting the numerical value itself, there are various reporting methods such as a case where the numerical value is classified and the rank is reported, and a case where the numerical value is reported by a graphic such as a bar graph. Can be applied.
[0063]
Further, in the above-described second embodiment, the case where the risk factor is determined based on the origin based on the fixed determination reference axes LX and LY has been described. However, the present invention is not limited to this. The determination reference axes LX and LY may be changed accordingly. Further, in the determination coordinate space based on the determination reference axes LX and LY, the angular ranges in the first and third quadrants are narrowed, that is, the determination reference axes LX and LY are inclined with respect to the original coordinate axes. As described above, the quadrant may be determined by performing coordinate transformation on the measurement result, so that only those with a high probability of danger may be notified. Incidentally, this coordinate conversion can be executed by calculating the amount of change in blood pressure and the amount of change in pulse value using a matrix.
[0064]
In the above-described embodiment, the case where the risk factor of the disease relating to the circulatory system is determined based on the change amount of the blood pressure value and the pulse value before and after the posture is changed, but the present invention The present invention is not limited to this. If the change appears as a change in blood pressure and pulse, the measurement may be performed before and after smoking, alcohol consumption, and alcohol consumption.
[0065]
Further, in the above-described embodiment, a case has been described in which the risk factor is determined simply based on the amount of change in the blood pressure value and the pulse value before and after changing the posture, but the present invention is not limited to this. The determination may be made after processing the amount of change in consideration of personal information such as weight, or the amount of change may be determined after processing the amount of change using an odds ratio such as age and weight. Good. It is conceivable that the information used for processing the amount of change is recorded and stored in a recording medium such as a memory card. In addition, in the process of the change amount, the change amount itself may be weighted according to the age, weight, and the like, and the determination reference side may be changed.
[0066]
Further, in the above-described embodiment, the case where the measurement is started by operating the start switch 10 and the attitude switch 14 has been described, but the present invention is not limited to this, and the start switch 10, the attitude switch 14, and the like are not essential. Instead, for example, the measurement may be automatically started when the power is turned on. It is also conceivable that the change in posture is detected, for example, from a change in pulse detected by a pressure sensor under two cuff pressures.
[0067]
In the above-described embodiment, the case where blood pressure and the like are separately measured before and after the posture change is described. However, the present invention is not limited to this. The blood pressure or the like may be measured using a meter.
[0068]
Further, in the above-described embodiment, the case where blood pressure and the like are measured before and after the posture change due to the sitting position and standing up has been described. However, the present invention is not limited to this. Can be widely applied. For example, for severely ill patients who cannot stand up, a supine position may be used as a reference for posture instead of standing up.
[0069]
Further, in the above-described embodiment, the case where the blood pressure measurement unit and the pulse measurement unit are integrally configured has been described. However, the present invention is not limited to this, and the blood pressure measurement unit and the pulse measurement unit are separately configured. Alternatively, another detection method such as a K-tone method may be used.
[0070]
Further, in the above-described embodiment, the case where the risk factor of cerebral infarction is determined has been described. However, the present invention is not limited to this, and if it relates to a circulatory disease, it relates to various diseases such as stroke. It can be widely applied to risk factor determination.
[0071]
Further, in the above-described embodiment, the case where the determination result is notified through the liquid crystal display unit has been described. However, the present invention is not limited to this. When notifying the determination result by outputting to a printer, a PDA (Personal Digital) is used. Various notification methods can be widely applied, for example, in the case of transmitting a judgment result to a candidate such as an assistant, a mobile phone, a computer, or the like.
[0072]
In the above-described embodiment, the case where the blood pressure measurement unit, the pulse measurement unit, and the data processing unit are integrally configured has been described. However, the present invention is not limited to this, and the blood pressure measurement unit, the pulse measurement unit, and the data processing unit may be integrated. The present invention can also be widely applied to a case where the means is configured separately. In this case, a computer or a dedicated analysis device capable of acquiring the measurement results of the blood pressure measurement unit and the pulse measurement unit by wireless communication or via a recording medium can be applied to the data processing unit. In this case, in the computer or the like, the process of acquiring the measurement results by the blood pressure measurement unit and the pulse measurement unit by wireless communication or the like is performed by first and second information for acquiring the blood pressure value and the pulse value before and after the subject's posture change. This constitutes an acquisition step.
[0073]
【The invention's effect】
As described above, according to the present invention, it is possible to easily determine a risk factor of a disease relating to a circulatory system by determining a change amount of a blood pressure value and a change amount of a pulse value before and after changing a posture. Can be. This can be useful for avoiding the onset of circulatory diseases such as cerebral infarction.
[Brief description of the drawings]
FIG. 1 is a flowchart for explaining a processing procedure of a control unit in a circulatory dynamics measuring device according to a first embodiment of the present invention.
FIG. 2 is a block diagram of the circulatory dynamics measuring device according to the first embodiment of the present invention.
FIG. 3 is a table provided for describing a determination method in the circulatory dynamics measuring device of FIG. 2;
FIG. 4 is a functional block diagram of the circulatory dynamics measuring device of FIG. 2;
FIG. 5 is a chart for explaining a determination method according to a second embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Circulation dynamics measuring device, 2 ... Cuff, 3 ... Circulating dynamics measuring device main body, 4 ... Power supply, 5 ... Pump, 6 ... Control unit, 7 ... Exhaust valve, 8 ... Pressure sensor, 11 changeover switch, 12 liquid crystal display section, 14 position switch

Claims (4)

A blood pressure measurement unit, a pulse measurement unit, and a data processing unit configured to process a blood pressure value by the blood pressure measurement unit and a pulse value by the pulse measurement unit,
The data processing means includes:
Calculate the change amount of the blood pressure value and the change amount of the pulse value before and after the subject changed the posture,
From the change amount of the blood pressure value and the change amount of the pulse value, determine a risk factor of a disease relating to the circulatory system,
A circulatory dynamics measuring device that reports the determination result. In the circulatory dynamic measurement device according to claim 1, the change amount of the blood pressure value is a change amount of the systolic blood pressure value,
The risk factor of the disease relating to the circulatory system is a risk factor of cerebral infarction,
The data processing means includes:
In a two-dimensional coordinate space based on coordinate axes corresponding to the change amount of the blood pressure value and the change amount of the pulse value, the risk factor is determined based on the position of the coordinate of the change amount value of the blood pressure and the change amount of the pulse value. Characteristic circulatory dynamics measurement device. The circulatory dynamics measuring device according to claim 1,
The change amount of the blood pressure value is a change amount of the pulse pressure,
The risk factor of the disease relating to the circulatory system is a risk factor of cerebral infarction,
The data processing means includes:
In a two-dimensional coordinate space for determination based on a determination reference axis corresponding to the change amount of the pulse pressure and the change amount of the pulse value, the quadrant of coordinates based on the change amount of the pulse pressure and the change amount of the pulse value indicates the risk. A circulatory dynamics measuring device characterized by determining a factor. A first information acquisition step of acquiring a blood pressure value and a pulse value before the subject's posture changes,
A second information acquisition step of acquiring a blood pressure value and a pulse value after the posture change of the subject;
A blood pressure value change amount calculating step of calculating a change amount between the blood pressure value obtained in the first information obtaining step and the blood pressure value obtained in the second information obtaining step;
A pulse value change amount calculating step of calculating a change amount between the pulse value obtained in the first information obtaining step and the pulse value obtained in the second information obtaining step;
A circulatory dynamics measuring method, comprising: a risk factor determining step of determining a cerebral infarction risk factor from the change amounts calculated in the blood pressure value change amount calculating step and the pulse value change amount calculating step.

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