KR20160026942A - Portable device for measuring blood pressure and method thereof - Google Patents

Abstract

The present invention relates to a portable blood pressure measurement device and method and, more specifically, to a portable blood pressure measurement device and method capable of measuring a blood pressure value of an artery of a wrist or a finger corresponding to a blood pressure value of an artery of an upper arm. To achieve the purpose, a finger-wearable blood pressure measurement device comprises: a blood pressure measurement unit to measure the blood pressure of a finger on which the device is mounted; a pulse wave transfer speed measurement unit which measures a pulse wave transfer speed from the finger on which the device is mounted; and a control unit which controls the measured blood pressure value of the artery of the finger measured by the blood pressure measurement unit to be corrected to correspond to the blood pressure value of the artery of the upper arm by using the pulse wave transfer speed measured by the pulse wave transfer speed measurement unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a portable blood pressure measurement device and a portable blood pressure measurement device.

The present invention relates to a portable blood pressure measuring apparatus and method, and more particularly, to a portable blood pressure measuring apparatus and method capable of measuring a blood pressure value of a wrist or a finger artery corresponding to a blood pressure value of the brachial artery.

One of the most useful information among various physiological signals for diagnosing human health is blood pressure. The clinical significance of blood pressure is an indicator of the abnormalities of the circulatory system including the heart and blood vessels. If the blood pressure tends to deviate from the normal value, continuous treatment is required. Arterial blood pressure fluctuates by heartbeat, and the ventricle contracts and the blood is pushed into the artery, the blood pressure is called systolic blood pressure. When the ventricles expand and the blood is not pushed out, the blood pressure is not zero because the artery wall has elasticity and the blood is being pressed. The blood pressure at this time is called the diastolic or diastolic blood pressure.

When a doctor or a nurse measures blood pressure in a hospital, it often happens that blood pressure is high due to tension. In addition, since blood pressure changes according to various conditions, it is difficult to make an accurate judgment by one measurement. Therefore, the necessity of home electronic blood pressure monitor has been raised in order to enable continuous measurement of blood pressure in the home. Currently the most widely used automated blood pressure monitors are using volume oscillometry. This method is a method of measuring blood pressure from oscillation generated by pressing / depressurizing an artery using a cuff, which is a method of estimating the cuff pressure when the pulse by the heartbeat has the maximum amplitude as the mean blood pressure to be. At this time, systolic and diastolic blood pressures are estimated as the cuff pressures having amplitude magnitudes of 45 to 57% and 74 to 82% of the maximum amplitude, respectively.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram schematically illustrating blood pressure measurement from a vibrating pressure of a cuff. FIG. As shown in FIG. 1, the systolic amplitude ratio and the diastolic amplitude ratio to the maximum amplitude are referred to as a characteristic ratio, which is different depending on the person, and is also influenced by the characteristics of the cuff, the characteristics of the arterial blood vessel, It is known.

 Most blood pressure monitors currently in use are designed to measure in the upper arm similar to the heart height, but many products capable of measuring blood pressure using a cuff on the wrist or finger have been studied and commercialized for convenience of measurement.

These wrist or finger blood pressure tonometers are smaller in size than the brachial blood pressure tester and are easy to carry and do not need to be removed. The signal to noise (S / N) ratio of the signal is basically low and therefore, the accuracy is lower than that of the brachial blood pressure monitor.

In addition, because the blood pressure may vary depending on the location of the artery due to various factors, the blood pressure measured on the wrist or finger type blood pressure meter may differ from the blood pressure measured on the upper arm, And serves as a cause of lowering the user's reliability on the measured value of the blood pressure monitor.

In the case of a conventional wrist or finger type blood pressure monitor, the arterial blood pressure is measured by the same oscillometry method as that of the brachial blood pressure monitor. If the sphygmomanometer is accurate and the blood pressure of the brachial artery is equal to the blood pressure of the wrist or finger artery, the blood pressure measured on the upper arm and the blood pressure measured on the wrist or finger are the same when the height of the wrist or finger is kept at the same height as the heart Should be.

In practice, however, the blood pressure of the brachial artery and the wrist or the brachial artery and the finger artery varies due to the flow characteristics of the blood flow.

That is, the blood pressure measured by the wrist or the finger may be higher than the blood pressure measured by the upper arm depending on the user, or may show a lower tendency.

2 is a graph showing the characteristics of blood pressure and waveform changes according to artery positions. FIG. 2 shows the pulse pressure varying with the distance from the aorta. It can be seen that the pulse pressure varies with age. That is, at lower ages, the difference between systolic and diastolic blood pressure increases as the distance from the aorta increases due to superimposition of reflected waves, but it tends to increase or even increase at higher ages. In addition, there is a disadvantage that if a user who is familiar with the brachial blood pressure meter used in the hospital can use the wrist or finger blood pressure monitor for the convenience of measurement and portability, have.

Accordingly, an object of the present invention is to provide a portable blood pressure measuring device and method capable of providing a user with a blood pressure value of a wrist or a finger artery corrected to correspond to a blood pressure value of a brachial artery having a variation by individual.

A finger-wearing blood pressure measuring apparatus for achieving the above object comprises: a blood pressure measuring unit for measuring a blood pressure of a finger artery in which the apparatus is mounted; A pulse wave transmission rate measuring unit for measuring a pulse wave transmission rate at a finger equipped with the apparatus; And a control unit for controlling the blood pressure measurement value of the finger artery measured by the blood pressure measurement unit to be corrected to correspond to the blood pressure value of the brachial artery using the pulse wave transmission rate measured through the pulse wave transmission rate measurement unit.

According to another aspect of the present invention, there is provided a method for measuring blood pressure of a finger-wearing blood pressure measuring apparatus, comprising the steps of: measuring blood pressure of a finger artery equipped with the apparatus; Measuring a pulse wave transmission rate at a finger equipped with the apparatus; And correcting the blood pressure measurement value of the finger artery to correspond to the blood pressure value of the brachial artery using the pulse wave transmission rate.

In other words, as described above, the present invention provides a portable blood pressure measurement device and method that effectively remove the individual deviation of the blood pressure of the wrist or the finger artery and the blood pressure of the brachial artery using the pulse wave transmission rate, There is an effect that the blood pressure of the artery can be corrected to the blood pressure of the brachial artery and provided to the user. In addition, since it is possible to ensure consistency between measured values of the upper arm blood pressure monitor measured at hospitals and wrists or finger-operated blood pressure monitors that are easy to carry personally, blood pressure measurement and management at any time can be facilitated.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a diagrammatic representation of blood pressure measurement from vibratory pressure of a cuff.
2 is a diagram showing the characteristics of blood pressure and waveform changes according to artery position.
3 is a diagram schematically illustrating measurement of a pulse wave transmission rate using an electrocardiogram signal and a pulse wave signal.
4 is a diagram showing pulse wave superposition characteristics according to the magnitude of the pulse wave transmission speed.
5 is a view showing a relationship between a blood pressure measured by the wrist and an upper arm and a pulse wave transfer rate.
6 is a view showing the relationship between the difference in blood pressure measured by the wrist and the upper arm and the pulse wave transfer velocity.
7 is a configuration diagram of a portable blood pressure measurement device according to an embodiment of the present invention.
8 is a view for explaining a portable blood pressure measuring apparatus according to the first embodiment of the present invention.
9 is a view for explaining a portable blood pressure measuring apparatus according to a second embodiment of the present invention.
10 is a flowchart illustrating a process of measuring blood pressure in a portable blood pressure measurement device according to an embodiment of the present invention.
11 is a view for showing a result of measuring blood pressure in a portable blood pressure measuring apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. It should be noted that the same configurations of the drawings denote the same reference numerals as much as possible.

To obtain the difference in blood pressure between the brachial artery and the wrist or the finger artery, information that can measure or estimate the individual deviation is needed in the conventional blood pressure measurement method, which can be measured by measuring the pulse wave transmission rate measuring the blood pressure. Therefore, in the present invention, the pulse wave velocity (PWV) is used as a means for correcting the individual blood pressure deviation of the brachial artery and wrist or finger artery.

3 is a diagram schematically illustrating measurement of a pulse wave transmission rate using an electrocardiogram signal and a pulse wave signal. 3, the time difference between the R peak of the electrocardiogram signal and the start point of the pulse wave signal measured using the optical sensor provided in the portable blood pressure measuring device worn on the wrist or the finger, that is, the pulse transit time (PTT) Represents the time taken from the contraction of the ventricle until the pulse wave signal is transmitted to the measurement point. When the distance from the heart to the measurement point of the pulse wave signal is divided by the PTT, the pulse wave propagation velocity is obtained, which is widely used as an index indicating the characteristics of blood vessels, in particular, atherosclerosis.

4 is a diagram showing pulse wave superposition characteristics according to the magnitude of the pulse wave transmission speed. The pulse wave signal generated by the contraction of the ventricle forms a reflected wave at a branching point or an end point of the artery and determines the size and shape of the pulse wave signal at a specific point according to the overlapping of the original pulse wave signal and the reflected wave as shown in FIG. .

As shown in FIG. 4 (b), when the pulse wave propagation velocity is low, superimposition of the reflected waves does not raise the maximum pressure of the original pulse wave signal. However, when the pulse wave propagation velocity is large as shown in (c) of FIG. 4, when the maximum pressure of the superimposed waveform, that is, the systolic pressure, is increased by overlapping the reflected waves, The amplification of the systolic blood pressure by the systolic blood pressure is also increased.

The overlapping of the pulse wave signals varies depending on the difference in the pulse wave transmission speed at the same point, but also varies depending on the distance from the point where the reflected wave is generated.

In other words, when the size and shape of the pulse wave signal measured in the brachial artery, which is relatively distant from the wrist or finger artery near the arterial end point where the reflected wave is generated, is different, this difference is due to the difference in the overlap time will be.

  4 (b) and 4 (b) are formed in the brachial artery when the pulse wave propagation velocity is low, for example, in the wrist artery as shown in FIG. 4 (c) and the difference in systolic blood pressure measured by the difference in maximum pressure shown in (c).

At this time, as the pulse wave velocity increases, the peak pressure due to the wave superposition of the wrist or the finger artery rises and the difference in systolic blood pressure with the brachial artery increases.

If the pulse wave velocity is extremely high due to severe arteriosclerosis, the waveform of the wrist or the finger artery and the brachial artery both have the same shape as in FIG. 4 (c), and in this case, And the difference in peak pressure of the brachial artery may be rather reduced. That is, in general, the wrist or finger arterial blood pressure and brachial artery blood pressure measured at the same height tend to increase as the pulse wave transmission rate is higher.

FIG. 5 is a graph showing the relationship between the blood pressure and the pulse wave transmission rate measured on the wrist and the upper arm. In order to confirm the tendency that the wrist or finger arterial blood pressure and the brachial artery blood pressure increase as the pulse wave transmission rate increases, The results are shown.

The blood pressure was measured at the heart height for 6 persons using an upper arm blood pressure meter (A & D, UA-767) and a wrist blood pressure meter (Citizen, CH-656C) using a cuff, The pulse wave transmission rate was measured from the pulse wave signal using the transmission type optical sensor and the pulse wave transmission rate and the average blood pressure difference between the wrist and the upper arm were shown in a graph. As expected, as the pulse rate increases, the difference in blood pressure measured between the wrist and upper arm increases.

6 is a graph showing the relationship between the difference in blood pressure measured by the wrist and the upper arm and the pulse wave transfer rate. In order to confirm whether the characteristics shown in FIG. 5 are applied to the pulse wave velocity and the blood pressure, the positions of the six wrists were changed with respect to the heart height. As a result, Resulting in a blood pressure difference of approximately -30 to 40 mmHg in the brachial artery. In this case, the difference in systolic blood pressure and diastolic blood pressure both have a correlation coefficient of about 0.9 with the pulse wave transmission rate.

The operation of the portable blood pressure monitor using the relationship between the difference in blood pressure measured in the wrist or the finger artery and the brachial artery and the pulse wave transmission rate will be described in detail with reference to FIGS. 7 to 10. FIG.

FIG. 7 is a configuration diagram of a portable blood pressure measuring apparatus according to an embodiment of the present invention, FIG. 8 is a view for explaining a portable blood pressure measuring apparatus according to the first embodiment of the present invention, FIG. 10 is a flowchart illustrating a process of measuring blood pressure in a portable blood pressure measurement apparatus according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 7, the blood pressure measuring unit 720 measures the blood pressure of the wrist or the finger artery, and transmits the measured blood pressure value to the control unit 710.

The pulse wave transmission rate measuring unit 730 measures the pulse wave transmission speed and includes an electrocardiogram electrode unit 731 and a photosensor unit 732.

The electrocardiograph electrode unit 731 is composed of at least two electrodes, and is assumed to be composed of three electrodes in the embodiment of the present invention. Two of the three electrodes of the ECG electrode unit 731 are provided inside the cuff of the portable blood pressure measuring apparatus and the remaining one electrode is provided outside the cuff. Or one of the three electrodes of the ECG electrode unit 731 may be provided inside the cuff of the portable blood pressure measurement device and the remaining two electrodes may be provided outside the cuff.

The optical sensor unit 732 may include a light source and a light receiving element, and may be provided in a cuff of the portable blood pressure measurement device or in a separate device attached to a finger.

The structure of the pulse wave propagation velocity measuring unit 730 will be described in detail with reference to FIG. 8 to FIG. FIG. 8 shows three kinds of electrodes 731a, 731b, and 731c for measuring an electrocardiogram signal on an existing blood pressure monitor mounted on the wrist, A separate device 800 is mounted within the cuff 770 where the cuff 732 abuts the wrist artery region or to the finger area.

8, two electrocardiogram electrodes (for example, (-) electrodes 731a (for example, electrodes 731a and 732b) are provided on the inside of the wrist blood pressure measuring device, that is, And a GND electrode 731b) and one electrocardiogram electrode (for example, a (+) electrode 731c) is disposed outside the display unit 750 or the cuff 770. Alternatively, one cuff 731 may be provided inside the cuff 770, and two cuffs 731a and 731b may be provided outside.

Since the ECG electrode mounted inside the cuff 770 is in contact with the arm on which the cuff 770 is mounted, when the blood pressure is measured, the finger of the cuff 770 on which the cuff 770 is not mounted, The electrocardiogram can be measured.

8, the measurement of the pulse wave for measuring the pulse wave propagation velocity may be performed by adding the transmission type photosensor portions 732a and 732b to a separate device 800 mounted on the finger, (Light source 732c, light receiving element 732d) on its inner side. Particularly, when the pulse wave signal is measured in the wrist artery, it is preferable to arrange the light source 732c and the light receiving element 732d such that the artery is positioned between the light source 732c and the photodiode 732d.

9 shows the finger-shaped blood pressure measuring device. In the case of the finger-shaped blood pressure measuring device, in order to measure the pulse wave transmission rate, an electrocardiogram electrode 730 is provided in the cuff 770, Should be added. Since the finger artery is small in size, a method of measuring the vibration using the optical sensor units 732a and 732b instead of using the oscillation of the cuff 770 may be used. In this case, unlike the wrist blood pressure measuring device, the optical sensor units 732a and 732b for applying the oscillometry method are added to the inside of the cuff 770, and the pulse wave transmission rate can be measured using the optical sensor units 732a and 732b.

However, when the pressure is applied to the outside of the arterial blood vessel by applying pressure to the cuff 770, the pulse wave transmission rate value changes. Thus, in the case of the finger blood pressure measurement apparatus, in addition to the optical sensor unit inside the cuff 770, It is preferable to additionally include a transmission type or reflection type optical sensor unit in a separate device 800 mounted on the display unit 800. [

The control unit 710 controls the overall operation of the portable blood pressure measurement device. When the blood pressure value of the wrist or the finger artery measured by the blood pressure measuring unit 720 is received, the control unit 710 measures the blood pressure value of the wrist or the finger artery stored in the memory 740 so as to correspond to the blood pressure value of the brachial artery The blood pressure value of the received wrist or finger artery is corrected using the pulse wave transmission speed received through the pulse wave transmission speed measuring unit 730. [

Further, the controller 710 controls the display unit 750 to display the blood pressure value of the wrist or the finger artery corrected to correspond to the blood pressure value of the brachial artery.

The memory 740 stores an equation for correcting the blood pressure measurement value of the wrist or the finger artery to correspond to the blood pressure value of the brachial artery. The correction formula is selected and stored in advance in any one of the following equations (1) - (3).

Equation 1: P _brachial = a + P _radial + c * PWV

P _Brachial = a + P _radial + c * PWV + d * PWV ²

_{PW bravial} = a + P _radial + c * PWV + d * PWV ² + e * PWV ³

P _brachial : blood pressure measurement of brachial artery.

P _radial : blood pressure measurement of wrist or finger artery.

PWV: Pulse wave delivery rate.

a, b, c, d, e: a constant measured through experiments to calibrate blood pressure measurements on the wrist or finger arteries.

The formula for correcting the blood pressure measurement value of the wrist or finger artery to correspond to the blood pressure value of the brachial artery can be selected by an experiment of the developer of the portable blood pressure measurement device. The developer of the portable blood pressure measurement device checks the correlation coefficient between the systolic blood pressure difference and the diastolic blood pressure difference and the pulse wave transmission rate through the experiment as shown in FIG. 6, and measures the blood pressure of the wrist or the finger artery May be selected and stored in the memory 740 so as to make the blood pressure value most similar to the measured blood pressure of the brachial artery. Alternatively, the developer of the portable blood pressure measuring apparatus can estimate and apply more correction equations in accordance with the experiment based on the equation P _brachial = f (P _{radial ,} PWV) .

Alternatively, a correction formula may be used in the blood pressure measurement mode only when any one of the equations previously selected by the user is stored while all the equations (1) - (3) are stored in the memory 740. The memory 740 may also store the corrected blood pressure of the wrist or finger artery.

The display unit 750 displays the blood pressure value of the wrist or finger artery corrected to correspond to the blood pressure value of the brachial artery in the blood pressure measurement mode of the portable blood pressure measurement apparatus. The key input unit 760 includes function keys for setting various functions of the portable blood pressure measurement device.

The operation of measuring the blood pressure in the portable blood pressure measuring apparatus as shown in FIGS. 7-9 will be described in detail with reference to FIG.

10 is a flowchart illustrating a process of measuring blood pressure in a portable blood pressure measurement apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to Figs. 7-9.

Referring to FIG. 10, when the blood pressure measurement is selected according to the input of the key input unit 760 in the portable blood pressure measurement apparatus, the control unit 740 detects the selection and switches the portable blood pressure measurement apparatus to the blood pressure measurement mode Proceed to step 1001.

In the blood pressure measurement mode, the blood pressure measurement unit 720 measures the blood pressure of the wrist or the finger artery through the vibration of the cuff in step 1002, and transmits the blood pressure value of the measured wrist or finger artery to the control unit 740 do.

The pulse wave transmission rate measuring unit 730 measures the pulse wave transmission rate through the electrocardiograph electrode unit 731 and the optical sensor unit 732 in step 1003 and transmits the measured pulse wave transmission rate to the controller 740. [ Lt; / RTI >

The controller 740 receives the blood pressure value of the wrist or the finger artery from the blood pressure measuring unit 720 and receives the pulse wave transmitting speed from the pulse wave transmitting speed measuring unit 730, The blood pressure value of the received wrist or finger artery is corrected to correspond to the blood pressure value of the brachial artery through step 1004.

The controller 740 proceeds to step 1005 in which the blood pressure value of the wrist or the finger artery corrected to correspond to the blood pressure value of the brachial artery is displayed on the display unit 750 in step 1004,

FIG. 11 is a diagram illustrating a result of measuring blood pressure in a portable blood pressure measuring apparatus according to an embodiment of the present invention. FIG. 11, blood pressure difference between the wrist artery and the brachial artery is reduced through the process as shown in FIG. 10 in a state where the blood pressure difference between the wrist artery and the upper arm is about -30 to 40 mmHg, Respectively. At this time, the above formula (1) is applied to the correction formula.

Although the embodiments of the present invention have been described in connection with the mobile terminal, various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments but should be determined by the equivalents of the claims and the claims.

Claims (12)

A finger-wearing blood pressure measuring device comprising:
A blood pressure measuring unit for measuring a blood pressure of the finger artery in which the apparatus is mounted;
A pulse wave transmission rate measuring unit for measuring a pulse wave transmission rate at a finger equipped with the apparatus; And
And a controller for controlling the blood pressure measurement value of the finger artery measured by the blood pressure measurement unit so as to correspond to the blood pressure value of the brachial artery using the pulse wave transmission rate measured by the pulse wave transmission rate measurement unit, Blood pressure measuring device.
The blood pressure monitor according to claim 1,
An electrocardiogram electrode unit for measuring an electrocardiogram signal; And
A finger-wearing blood pressure measuring device comprising an optical sensor part for measuring a pulse wave signal.
The electrocardiogram electrode unit according to claim 2,
At least two electrodes,
Wherein at least one of the at least two electrodes is provided in a cuff of the device and at least one of the at least two electrodes is provided outside the cuff.
The optical sensor unit according to claim 2,
A light source and a light receiving element,
A finger-wearing blood pressure measuring device provided inside a cuff of the device.
The apparatus of claim 1,
Wherein the blood pressure value of the finger artery is corrected to correspond to the blood pressure value of the brachial artery through any one of the following equations (1) - (3).
Equation 1: P _brachial = a + P _radial + c * PWV
P _Brachial = a + P _radial + c * PWV + d * PWV ²
P _brachial = a + P _radial + c * PWV + d * PWV ² + e * PWV ³
P _brachial : blood pressure value of brachial artery.
P _radial : blood pressure value of finger artery.
PWV: Pulse wave delivery rate.
a, b, c, d, e: constants measured through experiments to calibrate the blood pressure values of the finger arteries.
6. The method of claim 5,
The finger-wearing blood pressure measuring device according to claim 1, further comprising a memory in which any one of the equations (1) - (3) is stored in advance.
The method according to claim 1,
And a display unit for displaying a corrected blood pressure measurement value of the finger artery.
A method for measuring blood pressure of a finger-wearing blood pressure measuring apparatus,
Measuring the blood pressure of the finger artery in which the device is mounted;
Measuring a pulse wave transmission rate at a finger equipped with the apparatus; And
And correcting the blood pressure measurement value of the finger artery to correspond to a blood pressure value of the brachial artery using the pulse wave transmission rate.
9. The method of claim 8,
Wherein the pulse wave propagation velocity is measured through an electrocardiogram signal and a pulse wave signal.
9. The method of claim 8,
Wherein the correction of the measured blood pressure value of the finger artery is performed through any one of the following equations (1) - (3).
Equation 1: P _brachial = a + P _radial + c * PWV
P _Brachial = a + P _radial + c * PWV + d * PWV ²
P _brachial = a + P _radial + c * PWV + d * PWV ² + e * PWV ³
P _brachial : blood pressure value of brachial artery.
P _radial : blood pressure value of finger artery.
PWV: Pulse wave delivery rate.
a, b, c, d, e: constants measured through experiments to calibrate the blood pressure values of the finger arteries.
11. The method of claim 10,
Wherein any one of the equations (1) - (3) is previously stored.
9. The method of claim 8,
And displaying a corrected blood pressure measurement value of the finger artery.

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