KR20200069545A - Blood Pressure Meter And Method For Measuring Blood Pressure Using The Same - Google Patents

Abstract

The present invention discloses a blood pressure monitor and a blood pressure measuring method using the same. The blood pressure monitor according to the present invention includes: a parameter change amount calculation unit for calculating a change in blood flow parameter (PM) caused by an altitude difference between any two points where blood flow measurement is performed; And it includes a blood pressure calculating unit for calculating the blood pressure from the altitude difference between the two points where the blood flow measurement is made, the amount of change in the blood flow parameter and the blood flow parameter.
The present invention is a blood pressure monitor that measures blood pressure using a change in blood flow parameter caused by an altitude difference (height difference) of a measurement position, and more specifically, reflects a rapid change in blood vessel state with a large influence on blood pressure measurement along with blood flow in the blood pressure monitor in blood pressure calculation Since it is a blood pressure monitor capable of measuring blood pressure, it is possible to more accurately measure blood pressure at a measurement position from a change in blood flow parameter every time blood pressure is measured.

Description

Blood pressure meter and method for measuring blood pressure using the same

The present invention relates to a sphygmomanometer and a blood pressure measurement method, and more particularly, to a blood pressure monitor for calculating blood pressure using a change in blood flow parameter according to an altitude difference (height difference) of a blood flow measurement location and a blood pressure measurement method using the same.

In general, measuring the pressure that blood has on the walls of blood vessels is called blood pressure, and the heart repeats contraction and relaxation about 60 to 80 times a minute. When the heart contracts and pushes out blood, the pressure on the blood vessels is called'constriction blood pressure' and is called'highest blood pressure' because it is the highest. In addition, when the heart relaxes and receives blood, the blood vessel pressure is called'relaxed blood pressure' and is called'lowest blood pressure' because it is the lowest.

Normally, the blood pressure of normal people is 120 mmHg of constricted blood pressure and 80 mmHg of diastolic blood pressure. More than 1 out of 4 adults in Korea are hypertensive, and since the age of 40, this rate has been increasing rapidly. On the contrary, there are patients classified as hypotension.

The high blood pressure is a problem because it can cause other complications that can threaten life, such as eye disease, kidney disease, arterial disease, brain disease, and heart disease, if left without proper management of high blood pressure. Patients with or at risk of complications should continuously measure and manage blood pressure.

As the interest in diseases related to adult diseases and health, such as hypertension, has increased, various types of blood pressure measuring devices have been developed. Blood pressure measurement methods include a stethoscope (Korotkoff sounds) method, an oscillometric method, and a tonometric method.

The auscultation method is a typical pressure measurement method. In the process of depressurizing after blocking the flow of blood by applying sufficient pressure to a part of the body where arterial blood passes, the pressure at the moment the pulse sound is first heard is measured as systolic pressure. It is a method of measuring the pressure at the moment when the pulse sound disappears by diastolic pressure.

In addition, the oscillometric method and the tonometric method are methods applied to the digitized blood pressure measuring device. The oscillometric method, like the auscultation method, sufficiently pressurizes the body part passing through the arterial blood so that the blood flow of the artery is blocked, and then depressurizes the body part at a constant rate, or the pulse wave generated during the process of pressurizing the body part at a constant rate. It detects systolic blood pressure and diastolic blood pressure.

Here, the pressure at a certain level may be measured as systolic blood pressure or diastolic blood pressure compared to the moment when the amplitude of the pulse wave is maximum, and the pressure when the rate of change of the pulse wave amplitude is rapidly changed is measured as systolic blood pressure or diastolic blood pressure. You may.

Then, in the process of decompressing at a constant speed after pressurization, systolic blood pressure is measured ahead of the moment when the amplitude of the pulse wave is maximum, and diastolic blood pressure is measured later than the moment when the amplitude of the pulse wave is maximum. On the contrary, in the process of increasing the pressure at a constant speed, systolic blood pressure is measured later than the moment when the amplitude of the pulse wave is maximum, and diastolic blood pressure is measured before the moment when the amplitude of the pulse wave is maximum.

The tonometric method is a method capable of continuously measuring blood pressure using a size and shape of a pulse wave generated at this time by applying a certain pressure of a size that does not completely block the blood flow of the artery.

As described above, a device for measuring blood pressure in a variety of ways, that is, a blood pressure monitor is the most basic medical device for measuring blood pressure, which is the basis of a health index, and is generally provided in general hospitals as well as in individuals at home or sports centers. It is widely used to measure blood pressure.

Most of the blood pressure monitors currently being used are designed to measure at the upper arm similar to the height of the heart, but products for measuring blood pressure in a body part such as a wrist or finger are being developed for convenience in carrying and measuring. The wrist sphygmomanometer or finger sphygmomanometer described above has a small size compared to the upper arm sphygmomanometer and is convenient to carry and easy to measure at any time.

On the other hand, in the case of a conventional blood pressure monitor that measures blood pressure using pulse waves, for example, a blood pressure monitor that calculates blood pressure based on optical arterial wave (PPG) or other pulse wave propagation speed (PTT), instability may be caused by vascular conditions. And the accuracy of blood pressure measurement may be degraded.

Accordingly, the present inventor has developed a blood pressure monitor and a blood pressure acquisition method for measuring blood pressure using a change in blood flow parameters according to a height difference (height difference) of a blood flow measurement position.

Republic of Korea Patent Publication No. 10-2010-0118331, published on November 5, 2010 Republic of Korea Registered Patent No. 10-1844897, registered on March 28, 2018

The present invention; An object of the present invention is to provide a sphygmomanometer for calculating blood pressure using a change amount of blood flow parameter (a change in blood flow parameter) according to an altitude difference (height difference) of a blood flow measurement position and a blood pressure measurement method using the same.

An aspect of the present invention includes: a parameter change amount calculating unit for calculating a change in blood flow parameter (PM) caused by an altitude difference between two arbitrary points where blood flow measurement is performed; And it provides a blood pressure monitor including a blood pressure calculating unit for calculating the blood pressure from the altitude difference between the two points where the blood flow measurement is made, the amount of change in the blood flow parameter and the blood flow parameter.

The blood pressure calculation unit; The blood vessel resistivity may be calculated from the altitude difference according to the change in the blood flow parameter, and the blood pressure may be calculated using the blood vessel resistivity and the blood flow parameter.

The blood flow parameter (PM) is; The time interval between the optical artery wave (PPG), the arterial pressure, the amplitude of the arterial wave, and the adjacent poles (bones, floors) of the arterial wave, the electrical resistance pulse wave, the pulse transit time, and It may be any one of blood flow rates, but the example is not limited thereto.

The blood pressure monitor may further include a pulse transit time (PTT) detection unit for detecting the pulse transmission time. The PTT detection unit may include an electrocardiogram measurement unit for measuring an electrocardiogram (ECG) and a pulse wave measurement unit for measuring the pulse wave. The electrocardiogram measurement unit and the pulse wave measurement unit may be provided together in a wristband for a specific example of a body part, for example, a cuff that can be worn on a wrist.

In addition, the blood pressure monitor may further include a blood flow velocity measurement unit for detecting the blood flow velocity.

When the blood flow parameter is an optical arterial wave, the blood pressure monitor may further include an optical arterial wave measurement unit for detecting the optical arterial wave, and when the blood flow parameter is arterial pressure, the blood pressure monitor further includes an arterial pressure measurement unit for detecting the arterial pressure. can do.

In addition, when the blood flow parameter is an arterial electrical resistance pulse wave, the blood pressure monitor may further include an arterial electrical resistance pulse wave measurement unit for detecting the arterial electrical resistance pulse wave.

The vascular resistivity (B) can be calculated by the following [Equation 1].

[Equation 1]

(B is the vascular resistivity, △H is the altitude difference between any two points where blood flow measurement is made, △PM is the amount of blood flow parameter change between any two points)

The amount of change in the blood flow parameter may be a difference in pulse wave propagation time measured at two arbitrary points.

And the blood pressure can be obtained from the vascular resistivity and blood flow parameters using Equation 2 below.

[Equation 2]

(P ₁ is the blood pressure at a high position (H ₁ ) among any two points where blood flow is measured, PM _{1 is the} value of blood flow parameter measured at the height of H ₁ , B is the vascular resistance, and K is the adjustment constant)

The sphygmomanometer further comprises a setting part that sets the adjustment constant from blood pressures measured by other sphygmomanometers that are a reference for blood pressure setting.

Another aspect of the present invention: calculates the amount of change in the blood flow parameter (Parameter: PM) caused by the altitude difference between any two points where blood flow measurement is made, and the altitude difference between the two points where the blood flow measurement is made and the amount of change in the blood flow parameter And a blood pressure measurement method for calculating blood pressure from blood flow parameters.

The blood pressure measuring method includes: (a) calculating blood vessel resistivity from an altitude difference according to the change in the blood flow parameter; And it includes the step (b) of calculating blood pressure from the blood vessel resistivity and blood flow parameters: the blood vessel resistivity (B) can be calculated by the following [Equation 1].

[Equation 1]

(B is the vascular resistivity, △H is the altitude difference between any two points where blood flow measurement is made, △PM is the amount of blood flow parameter change between any two points)

And in step (b), the blood pressure is calculated from the blood vessel resistivity and blood flow parameters; The blood pressure can be obtained by the following [Equation 2].

[Equation 2]

(P ₁ is the blood pressure at a high position (H ₁ ) among any two points where blood flow is measured, PM _{1 is the} value of blood flow parameter measured at the height of H ₁ , B is the vascular resistance, and K is the adjustment constant)

The blood pressure measuring method may further include a setting step of setting the adjustment constant before the step (a).

In addition, the blood pressure measurement method may further include calculating a blood pressure change amount from an altitude difference between the arbitrary two points.

The present invention is a sphygmomanometer measuring blood pressure using a change in blood flow parameter caused by an altitude difference (height difference) of a measurement position, and more specifically, calculating a blood pressure with a blood flow in the sphygmomanometer and a rapid change in blood vessel state having a large influence on blood pressure measurement. Since it is a blood pressure monitor that can be reflected in, it is possible to more accurately measure blood pressure at a measurement position from a change in blood flow parameter every time blood pressure is measured, and accuracy of blood pressure, that is, reliability of the blood pressure monitor can be greatly improved.

Features and advantages of the present invention may be better understood with reference to the drawings described below along with a detailed description of an embodiment of the present invention described below, among the drawings:
1 is a block diagram showing the configuration of a blood pressure monitor according to an embodiment of the present invention;
Figure 2 is a schematic view showing a blood pressure monitor according to an embodiment of the present invention;
3 is a view showing an example of a blood pressure measurement method according to an embodiment of the present invention;
4 is a graph illustrating the calculation of pulse transit time (PTT), which is an example of blood flow parameters from electrocardiogram and pulse wave measured by an embodiment of the present invention;
5 is a flow chart schematically showing a blood pressure measuring method according to an embodiment of the present invention; And
6 is a developed view showing a blood pressure monitor according to another embodiment of the present invention;
7 is a view showing a state in which the blood pressure monitor shown in FIG. 6 is worn on the body (arm);
8 is a diagram illustrating another method of measuring pulse wave transmission time;
9 is a diagram illustrating a method of measuring blood velocity, which is another example of blood flow parameters; And
10 is a diagram illustrating blood flow parameters from another example of an arterial wave.

Hereinafter, preferred embodiments of the present invention, in which the object of the present invention can be specifically realized, will be described with reference to the accompanying drawings. In describing these embodiments, the same name and the same code are used for the same configuration, and additional descriptions thereof are omitted below.

Terms used in the present specification are used to describe embodiments of the present invention, and are not intended to limit the present invention. For example, terms including an ordinal number such as "first" and "second" may be used to distinguish between elements when describing elements of the same name, but do not define or limit the number of elements.

And when a component is said to be "connected" or "connected" to another component, it may be directly connected to or connected to the other component, but there is another component in the middle It should be understood that the relationship also includes an indirectly connected relationship.

In the present specification, terms such as “include” or “have” mean that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and one or more other features However, it should be understood that the existence of numbers, steps, actions, components, parts, or combinations thereof, ie, additional possibilities are not excluded.

The blood pressure monitor according to an embodiment of the present invention is a device for measuring blood pressure, and may be implemented as a portable blood pressure monitor, more specifically, a wearable measuring device of blood pressure. For example, an embodiment of the present invention may be provided as a portable blood pressure monitor that is worn on a human body and measures blood flow of a measurement target region (target region), such as a wrist or finger, and obtains a blood pressure value from the blood flow parameter.

Hereinafter, embodiments of the blood pressure monitor according to the present invention will be described with reference to the accompanying drawings.

1 to 4, an exemplary embodiment of a blood pressure monitor according to the present invention includes a parameter change amount calculation unit 10 for calculating a change amount (blood parameter change amount) of a blood flow parameter (Parameter: PM), a blood flow parameter, etc. It includes a blood pressure calculation unit 20 for calculating the blood pressure (blood pressure value) using the data. That is, this embodiment is a blood pressure monitor that measures a user's blood flow, calculates a change in blood flow parameters, and provides a blood pressure value.

The sphygmomanometer according to one embodiment of the present invention may be provided as a wearable sphygmomanometer, that is, a portable type, such as a wrist sphygmomanometer or finger sphygmomanometer that can be worn on a predetermined part of the human body, for example, a wrist or a finger. In addition, the present invention may be applied to a smart phone, for example, a blood pressure monitor that measures blood pressure by contacting a finger with a light measurement sensor of the smart phone.

The parameter change amount calculation unit 10 is configured to calculate a blood flow parameter change amount ΔPM generated by an altitude difference ΔH between any two points where blood flow is measured. In addition, the blood pressure calculating unit 20 calculates blood pressure from the altitude difference between two points at which blood flow is measured, the amount of change in the blood flow parameter, and the blood flow parameter. The blood pressure calculating unit 20 may calculate a blood pressure change amount generated by the above-described difference in altitude.

In the present embodiment, the parameter change amount calculation unit 10 and the blood pressure calculation unit 20 are data input from a signal detection sensor, such as a photo blood flow meter (PPG) or an altitude difference detector, which is an example of a sensor, for example, a pulse wave measuring device. It is a component included in the blood pressure monitor control module (C) for calculating the blood pressure using.

In more detail, the blood pressure calculating unit 20 calculates the blood vessel resistivity from the altitude difference according to the change amount of the blood flow parameter, and calculates the blood pressure using the blood vessel resistivity and blood flow parameter.

To this end, the blood pressure monitor according to the present embodiment further includes a blood pressure difference calculating unit 30 for calculating a blood pressure difference caused by an altitude difference (ΔH) between any two points, that is, a change in blood pressure due to the altitude difference, if necessary. It might be. And the blood pressure monitor further includes a parameter measurement unit 40 for obtaining the blood flow parameters.

Examples of the blood flow parameter PM include a time interval between the optical artery wave (PPG), the arterial pressure, the amplitude of the arterial wave, and neighboring poles (bones, floors) of the arterial wave, the arterial electrical resistance pulse wave, There are pulse transit time, blood flow rate, and the like, and the blood flow parameter is not limited to the above-described example.

In order to use the pulse wave propagation time as a blood flow parameter for calculating the blood pressure, the blood pressure monitor may include a pulse transit time (PTT) detector 41 for detecting the pulse wave propagation time as an example of the parameter measurement part 40. May be provided.

The PTT detection unit 41 may include an electrocardiogram measurement unit (electrocardiogram) 41a for measuring an electrocardiogram (ECG) and a pulse wave measurement unit 41b for measuring a pulse wave. The electrocardiogram measurement unit 41a and the pulse wave measurement unit 41b are provided with a cuff 110 that can be worn on a predetermined part of the body, for example, a wrist or an arm (upper arm), as shown in FIG. 2. Can be. Both ends of the cuff 110 may be detached by Velcro 120 or other detachable means.

Further, electrodes 41a for ECG measurement may be provided on the inner and outer surfaces of the cuff 110, respectively, although not shown, calculate blood pressure from blood flow parameters, control the blood pressure monitor, and output the calculated blood pressure. The control module (C) is embedded in the display device, and the display device may be mounted on the cuff 110 so that a user can visually check blood pressure. As another example of the parameter measurement unit 40, a blood flow rate measurement unit for detecting the blood flow rate described above may be applied.

Of course, when the blood flow parameter used for blood pressure measurement is optical arterial wave or arterial pressure, the blood pressure monitor may be provided with an optical arterial wave measuring unit for detecting optical arterial waves or an arterial pressure measuring unit for detecting the arterial pressure. When the blood flow parameter is an arterial electrical resistance pulse wave, the blood pressure monitor is provided with an arterial electrical resistance pulse wave measurement unit. For example, the above-described arterial electrical resistance pulse wave may be measured based on a body fat measurement technique using electrical resistance, more specifically, a body fat measurement device. When measuring body fat, the body fat is measured based on the electrical resistance of the skin. By using this principle, the pulse wave of the artery, that is, the pulse wave of the artery, can be measured by the electrical resistance of the artery.

An example of the pulse wave measuring unit 41b is a photoplethysmography (PPG), but is not limited thereto, and a sensor capable of measuring pulse wave, for example, a pressure sensor is also possible. Although not shown, a general photo blood flow meter includes a light emitting part and a light receiving part.

And the altitude difference detection of the blood flow measurement position can be performed by the altitude difference detection unit 50, the altitude difference detection unit 50, the acceleration sensor and the altitude sensor and the pressure sensor and at least one sensor of the differential amplifier and gyro sensor It can contain. The altitude difference detecting unit 50 can be any device that can measure a height difference (altitude difference) between arbitrary positions where blood flow measurement is made, and the altitude difference measured by the altitude difference detecting unit 50 is described above. It is input to a blood pressure difference calculator 30.

Of course, the altitude difference (ΔH) of the difference between the two points may be measured by hand using a ruler, such as a measuring tape, for example, and if the manually measured altitude difference is input to the blood pressure monitor, , A blood pressure difference (a change in blood pressure) generated by the altitude difference from the input altitude difference ΔH may be calculated by the blood pressure difference calculator 30.

The altitude difference detecting unit 50 is a configuration for detecting altitude change, and detects altitude of a target region, that is, a body part where blood pressure measurement is performed, and detects an altitude difference (height difference) between any two points where blood pressure measurement is performed.

For example, as shown in FIG. 3, when a person (user) wearing the blood pressure monitor 100 measures blood flow using the blood pressure monitor at the first height H1 and the second height H2, the altitude difference detecting unit 50 detects the height difference between the two positions described above.

And the blood vessel resistivity (B) can be obtained from the above-mentioned difference in altitude and the amount of blood flow parameter change.

The vascular resistivity (B) can be calculated by the following [Equation 1].

(B is the vascular resistivity, △H is the altitude difference between any two points where blood flow measurement is made, △PM is the amount of change in blood flow parameters caused by the altitude difference between any two points)

The amount of change in the blood flow parameter may be a difference in pulse wave propagation time (PTT) measured at any two points as described below.

In addition, the blood pressure calculating unit 20 may calculate blood pressure using the following [Equation 2] from the vascular resistivity and blood flow parameters. That is, blood pressure can be expressed as a product of vascular resistance and blood flow parameters.

(P ₁ is the blood pressure at a high position (H ₁ ) among any two points where blood flow is measured, PM _{1 is the} value of blood flow parameter measured at the height of H ₁ , B is the vascular resistance, and K is the adjustment constant)

The above-described blood pressure value P ₁ is a blood pressure value at a high position H ₁ among any two points where blood flow is measured.

In addition, the blood pressure difference calculating unit 30 may calculate the blood pressure difference ΔP generated by the altitude difference of the blood flow measurement position using the following [Equation 3], that is, the blood pressure change amount, but is not limited thereto.

(g is the acceleration of gravity, ρ is the density of blood, △H is the altitude difference between any two points where blood flow is measured)

Since there is a difference in the gravitational acceleration for each region, it is preferable that the gravitational acceleration is changed to the gravitational acceleration for each region and input to the blood pressure difference calculator 30. The gravity acceleration can be automatically set (changed) according to the user's current position. Further, the density ρ of the blood may be a measured value or a predetermined average value. For more accurate blood pressure calculation, it is preferable that the density of the blood is changed for each race and input to the blood pressure difference calculation unit 30. In more detail, the density of the blood is set by race, and it is preferable that the density of blood corresponding to the user's race is input to the blood pressure difference calculating unit 30 and applied to blood pressure measurement.

More specifically, the blood pressure P in the blood vessel may be expressed as [Equation 4] below.

(P is blood pressure at any vascular position, V is blood flow velocity, R is flow resistance)

Therefore, as shown in the example shown in FIG. 3, blood pressure measured at any two points, i.e., different heights (H ₁ , H ₂ ), is related to the following [Equation 5].

(P ₁ and P ₂ are each a height H ₁ and the pressure of H _2, V ₁ and V ₂ are each a height H ₁ and the pulse wave passes the blood flow rate of H _2, T ₁ and T ₂ is the height H ₁ and H ₂ respectively, time)

And, referring to Figure 4, the pulse wave propagation time, T ₁ is obtained at a height of H ₁ , T ₂ is obtained at a height of H ₂ , and a difference (ΔT) of pulse wave propagation time (PTT), which is an example of a change in the blood flow parameter , PTT change) can be calculated as follows.

Accordingly, when the difference (ΔT) of the pulse wave propagation time (PTT) described above is applied to the amount of change in the blood flow parameter, the vascular resistivity of Equation 1 may be expressed as follows.

And, when the pulse wave propagation time is applied to the blood flow parameter, and when the PTT change, that is, the difference in the pulse wave propagation time, is applied as a change in the blood flow parameter, the maximum blood pressure (P ₁ max) at H ₁ height is obtained as in [Equation 6] Can be.

In addition, when the H ₁ height is not the heart height, the blood pressure value obtained at the H ₁ height is corrected to the blood pressure of the heart height using a known blood pressure correction method, and then displayed through the blood pressure output unit 70, for example, a digital screen. Can be. Correction of blood pressure to the height of the heart is a known technique, so an additional description thereof is omitted.

For reference, the setting of the reference value in the blood pressure monitor may be performed through initial setting using blood pressure measured in a separate blood pressure monitor, and the blood pressure monitor setting may be implemented by the blood pressure monitor setting unit 60. Accordingly, the setting unit 60 may set the above-described adjustment constant K from blood pressure (blood pressure value) measured by another blood pressure monitor, which is a standard for setting the blood pressure monitor.

Referring to FIG. 5, a blood pressure measurement method, that is, a blood pressure calculation method according to an embodiment of the present invention, calculates a change amount of a blood flow parameter (Parameter: PM) caused by an altitude difference between two arbitrary points where blood flow is measured. , It is performed through the process of calculating the blood pressure from the altitude difference between the two points where the measurement of the blood flow is made, the amount of change in the blood flow parameter and the blood flow parameter.

The blood pressure measurement method may include calculating the blood flow parameter change amount (S110), and calculating the blood pressure from the altitude difference, blood flow parameter change amount, and blood flow parameter (S120).

More specifically, the blood pressure measurement method includes calculating a blood vessel resistivity from an altitude difference according to the change in blood flow parameter (S121), and calculating blood pressure from the blood vessel resistivity and blood flow parameter (S122), The vascular resistivity can be obtained in the manner exemplified in the above-described embodiment.

In the blood pressure measurement method, the amount of blood pressure change (blood pressure difference) from the altitude difference (ΔH) between any two points before, after, or simultaneously with step (a) of calculating the difference in the blood flow parameter, for example, the pulse transmission time difference; ΔP) may be further included.

In this embodiment, the blood pressure calculating step (S120) calculates the blood vessel resistivity from the altitude difference according to the change in the blood flow parameter (S121), calculates the blood pressure using the blood vessel resistivity and blood flow parameters (S122), and the blood vessel resistivity Can be calculated in the manner described in the above-described embodiment.

In addition, blood pressure calculation may be performed through [Equation 2] more specifically, [Equation 2] described above using the vascular resistivity and blood flow parameters.

Before calculating the blood flow parameter variation and blood pressure difference described above, blood flow parameter measurement (S10), for example, electrocardiogram and pulse wave measurement, is performed. Then, when the blood pressure is calculated through the above-described process, the user's blood pressure is output through the screen of the blood pressure monitor (S130), and the user can check his or her blood pressure through this.

6 and 7, another embodiment of a blood pressure monitor according to the present invention is a cuff blood pressure monitor 100A worn on a forearm (upper arm), an example of an electrocardiogram measurement unit 41a and a pulse wave measurement unit provided at different heights For example, a plurality of light blood flow measurement devices (41b), the electrocardiogram measurement unit (41a) and pulse wave measurement unit (41b) is provided with a cuff (110A) forearm, one electrode of the electrodes of the electrocardiogram measurement unit It is mounted on the cuff 110A and the other electrode is connected by a wire to be attached to other parts of the body.

According to the example shown in FIGS. 6 and 7, the PTT change can be obtained as in the embodiments shown in FIGS. 1 to 4 and applied to the blood flow parameter change amount. The height difference of the photo blood flow meter 41b becomes the altitude difference (ΔH) of the blood flow measurement position. Therefore, the user's blood pressure can be calculated in the manner described above.

FIG. 8 illustrates a method of measuring the blood flow velocity, and pulse waves are detected as shown in FIG. 8(b) at two points on the blood vessel A with a distance (s; blood vessel length between two points) between the blood flow measurement points. When, the difference (t) of the pulse wave transmission time occurs, from which the blood flow velocity (V=s/t) can be obtained. The pulse waves may be detected by a plurality of pulse wave measuring units 42a and 42b spaced apart from each other, for example, a photo blood flow meter or a pressure sensor. For reference, FIG. 9 illustrates another method of measuring the blood rate, and for example, a sensor 43 based on ultrasonic waves or electromagnetic waves (radar) may be applied.

10 is a graph illustrating another form of an arterial wave that can be measured in a blood pressure monitor. Referring to FIG. 10, the amplitude of the arterial wave (A: height difference between the maximum point and the minimum point) and the time interval (B ₁ , B ₂ , B ₃ , B ₄ ) between neighboring poles may be applied as a blood flow parameter. . The poles mean the points where the primary derivative is 0 (Zero), for example, and the time interval between neighboring poles means the time interval between neighboring goal-floor or floor-goal.

As described above, the embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the embodiments described above are those with ordinary knowledge in the art. It is obvious.

Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be changed within the scope of the appended claims and their equivalents.

10: parameter change amount calculation unit 20: blood pressure calculation unit
30: blood pressure difference calculation unit 40: parameter measurement unit
41: PTT detection unit 41a: ECG measurement unit
41b: pulse wave measurement unit 50: altitude difference detection unit
60: Sphygmomanometer setting unit 100, 100A: Sphygmomanometer
110, 110A: Cuff 120: Velcro

Claims (17)

A parameter change amount calculating unit for calculating a change in blood flow parameter (PM) caused by an altitude difference between any two points where blood flow measurement is performed; And
A blood pressure monitor including an altitude difference between two points at which the blood flow measurement is performed, a blood pressure calculation unit for calculating blood pressure from the blood flow parameter change amount and blood flow parameter. According to claim 1,
The blood pressure calculation unit; A sphygmomanometer characterized by calculating a blood vessel resistivity from an altitude difference according to the change in the blood flow parameter and calculating the blood pressure using the blood vessel resistivity and blood flow parameter. According to claim 2,
The blood flow parameter (PM) is; Optical artery wave (PPG), arterial pressure, amplitude of arterial wave, time interval between neighboring poles of arterial wave, arterial electrical resistance pulse wave, pulse transit time, and blood flow velocity Sphygmomanometer characterized in that. According to claim 3,
A blood pressure monitor further comprising a Pulse Transit Time (PTT) detector for detecting the pulse transmission time. The method of claim 4,
The PTT detection unit, characterized in that it comprises an electrocardiogram measuring unit for measuring the electrocardiogram (ECG) and a pulse wave measuring unit for measuring the pulse wave. According to claim 3,
A blood pressure monitor further comprising a blood flow velocity measurement unit for detecting the blood flow velocity. According to claim 3,
A blood pressure monitor further comprising an optical arterial wave measurement unit for detecting the optical arterial wave. According to claim 3,
A blood pressure monitor further comprising an arterial pressure measuring unit for detecting the arterial pressure. According to claim 3,
A blood pressure monitor further comprising an arterial electrical resistance pulse wave measurement unit for detecting the arterial electrical resistance pulse wave. According to claim 2,
The vascular resistivity (B) is a blood pressure monitor, characterized in that calculated by the following [Equation 1].
[Equation 1]

(B is the vascular resistivity, △H is the altitude difference between any two points where blood flow measurement is made, △PM is the amount of change in blood flow parameters caused by the altitude difference between any two points) The method of claim 10,
The blood flow parameter change amount is a blood pressure monitor characterized in that the difference in pulse wave propagation time measured at any two points. The method of claim 10,
A blood pressure monitor characterized in that the blood pressure is calculated from the vascular resistivity and blood flow parameters using Equation 2 below.
[Equation 2]

(P ₁ is the blood pressure at a high position (H ₁ ) among any two points where blood flow is measured, PM _{1 is the} value of blood flow parameter measured at the height of H ₁ , B is the vascular resistance, and K is the adjustment constant) The method of claim 12,
A blood pressure monitor further comprising a setting unit for setting the adjustment constant from blood pressure measured in another blood pressure monitor that is a reference to the blood pressure setting. Calculating the amount of change in the blood flow parameter (PM) caused by the altitude difference between any two points where blood flow measurement is made, and calculating the blood pressure from the altitude difference between the two points where the blood flow measurement is made, the amount of change in the blood flow parameter and the blood flow parameter How to measure blood pressure. The method of claim 14,
(A) calculating blood vessel resistivity from an altitude difference according to the change in the blood flow parameter; And
And (b) calculating blood pressure from the vascular resistivity and blood flow parameters:
The blood vessel resistivity (B) is a blood pressure measuring method, characterized in that calculated by the following [Equation 1].
[Equation 1]

(B is the vascular resistivity, △H is the altitude difference between any two points where blood flow measurement is made, △PM is the amount of change in blood flow parameters caused by the altitude difference between any two points) The method of claim 15,
In the step (b), the blood pressure is calculated from the blood vessel resistivity and blood flow parameters; The blood pressure is a blood pressure measuring method, characterized in that calculated by the following [Equation 2].
[Equation 2]

(P ₁ is the blood pressure at a high position (H ₁ ) among any two points where blood flow is measured, PM _{1 is the} value of blood flow parameter measured at the height of H ₁ , B is the vascular resistance, and K is the adjustment constant) The method of claim 16,
And a setting step of setting the adjustment constant before the step (a).

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