KR20220153790A - Blood Pressure Meter And Method For Measuring Blood Pressure Using The Same - Google Patents

Abstract

The present invention discloses a blood pressure measuring system and a blood pressure measuring method for measuring blood pressure by using a cardiac output time parameter. The blood pressure measuring system according to the present invention measures vascular resistance from a blood flow parameter and an arterial pressure parameter detected in a part of the body, and computes a blood pressure value by using the vascular resistance and cardiac output time parameters. According to the present invention, it is possible to provide a subject's accurate blood pressure, that is, the blood pressure value at the heart level based on the cardiac output time parameters and the vascular resistance, regardless of any difference of the above-described parameters in height (altitude) between a detection site (where the blood pressure is measured) and the heart.

Description

Blood pressure measuring system and blood pressure measuring method using the same {Blood Pressure Meter And Method For Measuring Blood Pressure Using The Same}

The present invention relates to a blood pressure measurement system and a measurement calculation method using the same, and more particularly, to a blood pressure measurement system (sphygmomanometer) for calculating blood pressure using a cardiac output time parameter detected in a part of the body and a blood pressure measurement method using the same It is about.

In general, blood pressure is a measurement of the pressure exerted by blood on the walls of blood vessels, and the heart repeats contraction and relaxation about 60 to 80 times per minute. The pressure exerted on the blood vessels when the heart contracts and pushes blood is called 'systolic blood pressure', and because it is the highest, it is called 'systolic blood pressure'. In addition, when the heart relaxes and accepts blood, the blood vessel pressure is called 'diastolic pressure', and because it is the lowest, it is called 'diastolic pressure'.

In normal blood pressure, the systolic blood pressure is 120 mmHg and the diastolic blood pressure is 80 mmHg. More than 1 out of 4 adults in Korea has high blood pressure, and since the age of 40, this rate has been rapidly increasing, and on the contrary, some patients are classified as hypotensive.

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 high blood pressure is not properly managed. For patients at risk of or with complications, continuous blood pressure measurement and management should be performed.

As interest in diseases related to adult diseases such as the aforementioned hypertension and health increases, various types of blood pressure measuring devices are being developed. Blood pressure measurement methods include a Korotkoff sounds method, an oscillometric method, a tonometric method, and the like.

The auscultation method is a typical pressure measurement method. In the process of applying sufficient pressure to the body part through which arterial blood passes to block the flow of blood and then reducing the pressure, the pressure at the moment when the pulse sound is heard for the first time is measured as systolic pressure. The pressure at the moment when the sound of the pulse disappears is measured as diastolic pressure.

In addition, the oscillometric method and the tonometric method are applied to the digitized blood pressure measuring device. Like the auscultation method, the oscillometric method detects pulse waves generated during the process of sufficiently pressurizing a body part through which arterial blood passes and then depressurizing the body part at a constant speed so as to block blood flow in the artery, or in the process of pressurizing the body part at a constant speed to increase the pressure. It detects and measures systolic and diastolic blood pressure.

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

In addition, in the process of decompressing at a constant rate after pressurization, the systolic blood pressure is measured before the moment when the amplitude of the pulse wave is maximum, and the diastolic blood pressure is measured after the moment when the amplitude of the pulse wave is maximum. Conversely, in the process of increasing pressure at a constant rate, the systolic blood pressure is measured later than the moment when the amplitude of the pulse wave is maximum, and the diastolic blood pressure is measured before the moment when the amplitude of the pulse wave is maximum.

The tonometric method is a method in which a certain amount of pressure that does not completely block arterial blood flow is applied to a body part, and blood pressure can be continuously measured using the size and shape of a pulse wave generated at this time.

As described above, a device that measures blood pressure in various 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. It is widely used for measuring blood pressure, and recently, a portable blood pressure monitor is also being developed.

In order to increase the accuracy of blood pressure measurement described above, blood pressure measurement should be performed at a body part at the level of the heart, and when blood pressure measurement is performed at a location where blood pressure detection is convenient, such as the wrist, the height (altitude) of the wrist and heart at the time of blood pressure measurement The blood pressure difference according to the difference should be reflected in the blood pressure calculation.

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

The present invention; An object of the present invention is to provide a blood pressure measuring system that calculates a blood pressure value of a subject using a cardiac output time parameter detected in the body through a sensor unit, and a blood pressure measuring method using the same.

More specifically, the present invention; A blood pressure measuring system that calculates a blood vessel resistance rate from a blood flow parameter and an arterial pressure parameter detected by a sensor unit at a part of the body, and calculates a blood pressure value using the blood vessel resistance rate and a cardiac output time parameter detected from the sensor unit, and using the same Its purpose is to provide a method for measuring blood pressure.

One aspect of the present invention includes: a sensor unit for detecting a cardiac ejection time parameter in a body; And a blood pressure measurement system including a blood pressure calculation unit that calculates a blood pressure value using the cardiac output time parameter is provided.

Through the sensor unit, it is possible to detect a blood flow parameter and an arterial pressure parameter together with the cardiac ejection time parameter; The blood pressure calculating unit calculates the blood pressure value by using the cardiac ejection time parameter, blood flow parameter, and arterial pressure parameter.

The blood pressure calculation unit; A blood vessel resistivity may be calculated from the blood flow parameter and the arterial pressure parameter, and the blood pressure value may be calculated using the blood vessel resistivity and the cardiac output time parameter.

In the Hagen-Poise equation below, assuming that the blood flow rate (Q)=πr ² V and V is the blood flow velocity, it can be seen that the vascular resistivity (R=ΔP/V ) is a value that reflects the blood viscosity and the radius of the blood vessel. .

<Hagen-Poage's Equation>

In the Hagen-Poise equation above, μ is the blood viscosity, ΔP is the increase and decrease in blood pressure, l is the length of the blood vessel, Q is the blood flow in the blood vessel, and r is the radius of the blood vessel.

Q=πr ² V (V is blood flow velocity), and R (vascular resistivity)=ΔP/V=8ul/r ² .

In the present invention, the vascular resistivity is calculated by the following [Equation 1]; The blood pressure value can be obtained by the following [Equation 2].

[Equation 1]

(R is vascular resistivity, AM is arterial pressure parameter, BM is blood flow parameter)

[Equation 2]

(BP is blood pressure value, TM is cardiac ejection time parameter, R is vascular resistivity, K is adjustment constant)

The blood pressure measurement system may further include a setting unit for setting the adjustment constant.

The arterial pressure parameter may be one of magnitudes of arterial wave feature points detected by a pressure sensor of the sensor unit. For example, a height difference between arterial wave feature points, an average height of feature point sections, and the like may be applied as the arterial pressure parameter.

The cardiac output time parameter may be one of time intervals of arterial wave feature points. For example, the time interval between the opening and closing of the aortic valve may be applied as an example of the cardiac output time parameter.

The blood flow parameter relates to blood flow and may be one of blood flow velocity and arterial wave characteristic value (PWA).

The blood flow parameter may be a time interval between a cardiac output wave and a reflected wave, which is one of arterial wave characteristic values (PWA).

The sensor unit may include one or more sensors from the group consisting of a pressure sensor, a blood flow rate sensor, an optical sensor, an impedance sensor, an electrocardiogram sensor, an ultrasonic sensor, and a radar sensor.

The blood pressure calculation unit; The arterial pressure parameter may be obtained as a difference between a systolic blood pressure value and a diastolic blood pressure value of a region measured by the sensor unit. The systolic blood pressure value and the diastolic blood pressure value may be obtained by an oscillometric blood pressure measurement method .

The sensor unit; It can be installed on one part of the finger, wrist, wrist, forearm, and earlobe.

Another aspect of the present invention is a blood pressure measurement method for calculating a blood pressure value using a biosignal detected from the body: calculating a blood pressure value using a cardiac output time parameter detected in a part of the body through a sensor unit. A blood pressure measurement method is provided. More specifically, the method for measuring blood pressure according to the present invention may calculate a blood pressure value using a cardiac output time parameter, an arterial pressure parameter, and a blood flow parameter. According to the present invention, a processor for calculating blood pressure may calculate the blood pressure value from the cardiac output time parameter, the blood flow parameter, and the arterial pressure parameter.

The blood pressure measuring method; A parameter acquiring step of acquiring the cardiac output time parameter through the sensor unit and a blood pressure calculating step of calculating the blood pressure value using the cardiac ejection parameter may be included.

More specifically, the blood pressure measurement method; (a) obtaining a blood flow parameter and an arterial pressure parameter along with the cardiac ejection time parameter through the sensor unit; (b) calculating a blood vessel resistivity from the blood flow parameter and the arterial pressure parameter; The method may further include a step (c) of calculating the blood pressure value using the vascular resistivity and the cardiac ejection time parameter.

The step (a) is; A difference between a systolic blood pressure value and a diastolic blood pressure value in a region measured by the sensor unit may be obtained as the arterial pressure parameter.

The systolic blood pressure value and the diastolic blood pressure value may be obtained by an oscillometric blood pressure measurement method.

The step (b) includes calculating the vascular resistivity using the following [Equation 1]; The step (c) may include obtaining the blood pressure value using the following [Equation 2] to [Equation 6].

[Equation 1]

(R is vascular resistivity, AM is arterial pressure parameter, BM is blood flow parameter)

[Equation 2]

(BPmin is the diastolic blood pressure value, TMS is the sum of cardiac output time parameters for a certain period of time, K1 is the first adjustment constant)

At this time, in TMS, in addition to the sum of the cardiac output time parameters, the product of the cardiac output time parameter and the pulse period (TM x pulse period) or the product of the cardiac output time parameter and the number of pulses during a certain period of time (TM x the number of pulses during a certain period of time) can be used

or

[Equation 3]

(BPac is the systolic blood pressure value-diastolic blood pressure value, TM is the cardiac output time parameter, K2 is the second adjustment constant)

[Equation 4]

(BPmax is the systolic blood pressure value)

The blood pressure measurement method according to the present invention; Before the step (c), a setting step of setting the adjustment constants may be further included. More specifically, the adjustment constants K1 and K2 may be determined by [Equation 5] and [Equation 6] below.

[Equation 5]

(CBPmin is the diastolic blood pressure value measured by the reference blood pressure monitor (master blood pressure monitor) for setting the blood pressure monitor, and TMS is the sum of the parameters of cardiac output for a certain period of time)

[Equation 6]

(CBPac is the blood pressure difference (systolic blood pressure value - diastolic blood pressure value) provided by the reference blood pressure monitor (master blood pressure monitor) for blood pressure monitor setting, TM is the cardiac ejection time parameter)

When the arterial pressure parameter is measured by the oscillometric blood pressure measurement method, setting of the adjustment constant is unnecessary. However, when the arterial pressure parameter is measured by the optical method or the blood flow velocity method and the tonometric blood pressure measurement method, the setting of the adjustment constant is necessary.

The present invention is a blood pressure measurement system for measuring blood pressure using vascular resistivity and cardiac ejection time parameters, and more specifically, blood pressure using vascular resistivity and cardiac ejection time parameters by arterial pressure parameters and blood flow parameters detected in a part of the body. Since it is a sphygmomanometer that calculates blood pressure and a blood pressure measurement method using the same, based on the cardiac output parameter and vascular resistivity, regardless of the difference in height (altitude) between the measurement site and the heart, the subject's blood pressure, that is, the blood pressure at the heart level can be more accurately provided. , the reliability of the blood pressure monitor can be greatly improved.

The features and advantages of the present invention may be better understood with reference to the following drawings in conjunction with the detailed description of the embodiments of the present invention, of which:
1 is a block diagram showing the configuration of a blood pressure measuring system according to an embodiment of the present invention;
2 is a diagram schematically illustrating a body application position of a blood pressure measuring system according to an embodiment of the present invention;
3 is a flowchart schematically illustrating a method for measuring blood pressure according to an embodiment of the present invention;
4 is a diagram illustrating a state in which a blood pressure measuring system according to an embodiment of the present invention is worn on a human body;
5 is a diagram showing an example of blood flow parameter detection using an optical sensor of the blood pressure measuring system shown in FIG. 4;
6 is a diagram illustrating a wrist blood pressure monitor as the blood pressure measuring system shown in FIG. 4;
7 is a diagram showing an example of blood flow parameter detection by a blood pressure measurement system according to another embodiment of the present invention;
8 is a diagram illustrating a forearm blood pressure monitor as a blood pressure measuring system according to another embodiment of the present invention;
9 is a graph illustrating arterial wave feature values;
10 is a diagram illustrating a structure for detecting a change amount of an arterial impedance wave, which is another example of a blood flow parameter;
11 is a view for comparing the shape of an arterial wave with the point at which a semilunar valve of the heart opens and closes; and
12 is a diagram showing a time interval Tfb between a cardiac output wave (Wf) and a reflected wave (Wb) in an arterial wave (W).

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In describing the present embodiments, the same names and the same reference numerals are used for the same components, and additional descriptions thereof are omitted below.

Terms used in this specification are used to describe embodiments of the present invention, and are not intended to limit the present invention. For example, terms including ordinal numbers such as “first” and “second” may be used to distinguish components having the same name from each other, but do not define or limit the number of components.

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

In this specification, terms such as "include" or "have" mean that features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, and that one or more other features are present. However, it should be understood that the existence of numbers, steps, operations, components, parts, or combinations thereof, i.e., the possibility of addition is not excluded.

A blood pressure measurement system according to embodiments of the present invention is a device that detects biometric parameters from the body, in particular, cardiac output time parameters from a subject (user) and calculates blood pressure using the detected parameters. More specifically, embodiments of the present invention are devices for detecting blood flow parameters and arterial pressure parameters together with the cardiac output time parameters and calculating blood pressure using them, and more specifically, a wearable measuring device of a personal portable blood pressure monitor. Blood Pressure) or blood pressure monitors used in medical institutions or nursing facilities. Embodiments of the present invention are portable/non-portable blood pressure monitors that derive vascular resistivity based on blood flow parameters and arterial pressure parameters detected from the body, and obtain blood pressure values using the vascular resistivity and cardiac output parameters detected from the body. It may be provided in various types of blood pressure monitors, such as. In this specification, the term 'body' includes not only a human body but also the body of an animal other than a human being, and includes not only the torso but also leg parts, such as limbs and head.

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

First, referring to FIGS. 1 to 3, an embodiment (first embodiment) of a blood pressure monitor according to the present invention includes a sensor unit 100 for detecting a cardiac ejection time parameter (TM) in a part of the body; And a blood pressure calculation unit 200 for calculating the blood pressure, that is, a processor.

An arterial pressure parameter (AM) and a blood flow parameter (BM) may be additionally detected along with the cardiac output time parameter through the sensor unit 100, and the blood pressure calculation unit 200 uses the sensor unit 100 to The blood pressure value (BP) is calculated using physiological parameters acquired from the body through the above-described cardiac output time parameter (TM), arterial pressure parameter (AM), and blood flow parameter (BM).

That is, the present embodiment is a blood pressure measurement system that calculates a blood pressure value (BP) using a biosignal sensed from a part of the body, and includes the sensor unit 100 and the blood pressure calculation unit 200 described above.

In this embodiment, the blood pressure calculation unit 200 calculates the vascular resistivity R from the arterial pressure parameter AM and the blood flow parameter BM, and calculates the vascular resistivity R and the cardiac output time parameter TM ) is used to calculate the subject's blood pressure value (BP).

In other words, in this embodiment, the blood pressure calculation unit 200 calculates the blood pressure value BP, that is, the blood pressure value of the subject, using the above-described cardiac output time parameter and vascular resistivity.

The blood pressure calculation unit 200 may obtain a difference between a systolic blood pressure value (systolic arterial pressure) and a diastolic blood pressure value (diastolic arterial pressure) of a region measured by the sensor unit 100 as the arterial pressure parameter (arterial pressure difference). have. In other words, the difference between the highest blood pressure value (highest arterial pressure) and the lowest blood pressure value (lowest arterial pressure), ie, the arterial pressure difference, at the site where the biosignal is measured by the sensor unit 100 may be applied as the arterial pressure parameter.

To this end, in this embodiment, the cardiac ejection time parameter (TM), the arterial pressure parameter (AM), and the blood flow parameter (BM) are detected through the sensor unit 100, and the blood flow parameter (BM) and the arterial pressure parameter ( The vascular resistivity is determined by AM), and the subject's blood pressure value is obtained using the vascular resistivity R and the cardiac ejection time parameter TM.

For example, based on the biosignal sensed by the sensor unit 100, biometric parameters, that is, the above-described cardiac ejection time parameter (TM), arterial pressure parameter (AM), and blood flow parameter (BM) may be detected. To this end, the blood pressure measurement system according to the present embodiment may include a parameter detector 140 that obtains physiological parameters by processing the physiological signals.

The sensor unit 100 may include at least one sensor selected from the group consisting of a pressure sensor, a blood flow rate sensor, an optical sensor, an impedance sensor, an electrocardiogram sensor, an ultrasonic sensor, and a radar sensor.

For example, the sensor unit 100 may include a pressure sensor for detecting at least one biological parameter among the arterial waveform parameter, arterial pressure parameter, and blood flow parameter.

More specifically, for example, when an arterial wave is detected by the pressure sensor 110 as an example of a biosignal, the above-described biometric parameter, for example, the arterial pressure parameter, based on the arterial wave is detected by the parameter detector 140 ) can be detected by The parameter detector 140 may be applied as a part of the above-described sensor unit 100, or may be a component of the processor C together with the above-described blood pressure calculation unit 200.

The systolic blood pressure value (BP _max ) and the diastolic blood pressure value (BP _imin ) measured by the sensor unit 100 may be obtained by an oscillometric blood pressure measurement method.

In the present embodiment, the vascular resistivity (R) is calculated by the following [Equation 1], and the blood pressure value (BP) can be obtained by the following [Equation 2] to [Equation 6].

(R is vascular resistivity, AM is arterial pressure parameter, BM is blood flow parameter)

Therefore, the subject's diastolic blood pressure can be obtained as follows [Equation 2].

(BPmin is the diastolic blood pressure value, TMS is the sum of cardiac output time parameters for a certain period of time, K1 is the first adjustment constant)

At this time, in TMS, in addition to the sum of the cardiac output time parameters, the product of the cardiac output time parameter and the pulse period (TM x pulse period) or the product of the cardiac output time parameter and the number of pulses during a certain period of time (TM x the number of pulses during a certain period of time) can be used

or

(BPac is the systolic blood pressure value - the diastolic blood pressure value, TM is the cardiac output time parameter, and K2 is the second adjustment constant)

(BPmax is the systolic blood pressure value)

The blood pressure measurement system according to the present embodiment, for example, a blood pressure monitor, may further include a setting unit 210 for setting the adjustment constants K1 and K2. And the adjustment constants (K1, K2) can be determined by [Equation 5] and [Equation 6] below.

(CBPmin is the diastolic blood pressure value measured by the standard blood pressure monitor (master blood pressure monitor) for setting the blood pressure monitor, and TMS is the sum of the parameters of cardiac output during a certain period of time)

(CBPac is the blood pressure difference (systolic blood pressure value - diastolic blood pressure value) provided by the reference blood pressure monitor (master blood pressure monitor) for blood pressure monitor setting, TM is the cardiac ejection time parameter)

The sensor unit 100 for detecting the aforementioned biological parameters may include at least one sensor selected from the group consisting of a pressure sensor, a blood flow rate sensor, an optical sensor, an impedance sensor, an electrocardiogram sensor, an ultrasonic sensor, and a radar sensor. can

More specifically, the sensor unit 100 may include a first sensor 110 for detecting an arterial pressure parameter and a cardiac output time parameter, and a second sensor 120 for detecting a blood flow parameter. . The first sensor 110 may be an arterial pressure measuring sensor, and the second sensor 120 may be a blood flow measuring sensor. For example, a pressure sensor may be applied as the first sensor 110 and a blood flow velocity sensor may be applied as the second sensor 120 .

The cardiac output time parameter may be one of time intervals of arterial wave feature points in a region where a biosignal is measured by the sensor unit 100 .

The sensor unit 100 may be installed (wear) on any one of body parts, such as a finger, wrist, wrist, forearm, and earlobe, where arterial pressure can be easily measured. In FIG. 2, the wearable parts S1, S2, S3, and S4 of the sensor unit 100 are variously exemplified, and as the sensor of the sensor unit 100, one sensor, for example, only one pressure sensor may be applied. There is, and a plurality of sensors, for example, the above-described first sensor 110 and second sensor 120 may be applied. The sensor unit 100 detects a biosignal for blood pressure measurement at a part where arterial pressure can be easily detected, for example, a wrist or a finger as described above.

The sensor unit 100 may be wired or wirelessly connected to the above-described processor C, and the biosignal detected by the sensor unit 100 may be transmitted to the processor C through wired or wireless. For example, the Internet of Things may be applied to the transmission of biosignals.

The finally calculated blood pressure value of the subject may be output to the blood pressure output unit 300, for example, a display device, and the display device may be mounted on the sensor unit 100 or may be a part or a second sensor unit. 200 may be provided in any one of the mounted parts, may be separately separated from the sensor unit 100 and connected by wire or wirelessly, or may be provided with the above-described processor C in the display device. have.

The sensor unit 100 is a component (sensor installation unit) that wears the above-described at least one sensor on the biosignal measuring part, for example, a band that wraps around the wrist, that is, a wrist strap (131; Wrist Strap), or an upper arm. A band or cuff 132 may be included, and the processor C may be mounted on the sensor installation unit 130 .

Referring to FIG. 3 , a blood pressure measurement method, that is, a blood pressure providing method according to an embodiment of the present invention is a blood pressure measurement method that calculates a blood pressure value using a biosignal detected from the body, and in particular, cardiac output time through a sensor unit. The parameter TM is detected, and the blood pressure is calculated (calculated) using it. For example, the method for measuring blood pressure according to an embodiment of the present invention includes a parameter acquisition step of acquiring the cardiac output time parameter through the sensor unit, and blood pressure calculation of calculating the blood pressure value using the cardiac output parameter. steps may be included.

More specifically, the method for measuring blood pressure according to an embodiment of the present invention detects an arterial pressure parameter (AM) and a blood flow parameter (BM) together with a cardiac ejection time parameter (TM) in the body through the sensor unit, and The blood pressure value of the subject may be calculated using the cardiac output time parameter, the arterial pressure parameter, and the blood flow parameter.

For example, a blood pressure value is calculated from a blood flow parameter, an arterial pressure parameter, and a cardiac output time parameter detected at a part of the body, such as a wrist or forearm (upper arm), through the sensor unit 100 described above.

The method for measuring blood pressure according to an embodiment of the present invention includes steps (a) of obtaining a biometric parameter through the sensor unit 100 (S110), step (b) of calculating vascular resistivity (S120), and blood pressure. A step (c) of calculating the value BP (S130) may be included.

More specifically, the step (a) (S110) is a step of acquiring a blood flow parameter (BM), an arterial pressure parameter (AM), and a cardiac ejection time parameter (TM). For example, a biometric parameter may be detected based on a biometric signal, that is, biometric data sensed by a pressure sensor (S100).

The step (b) (S120) is a step of calculating the vascular resistivity (R) from the blood flow parameter and the arterial pressure parameter, and the step (c) (S130) is the step of calculating the vascular resistivity (R) and the cardiac output time parameter ( This step is to calculate the blood pressure value (BP) using TM).

In the step (a), the difference between the systolic blood pressure value (BP _max ) and the diastolic blood pressure value (BP _min ) of the region measured by the sensor unit 100, that is, the arterial pressure difference is obtained (determined) as the arterial pressure parameter (AM). )You may. That is, an arterial pressure difference may be applied as an arterial pressure parameter, and the arterial pressure parameter (AM) may be expressed as follows.

Arterial pressure parameter (AM) = systolic blood pressure value (BP _max ) - diastolic blood pressure value (BP _min ) = arterial pressure difference

To calculate the arterial pressure parameter, a systolic blood pressure value and a diastolic blood pressure value may be measured by an oscillometric blood pressure measurement method.

In this embodiment, the step (b) (S120) includes calculating the blood vessel resistivity (R) using the above-described [Equation 1]. and; Step (c) (S130) may include obtaining the blood pressure value BP using [Equation 2] to [Equation 6] described above.

The blood pressure measurement method according to the present embodiment may further include a setting step (S140) of setting the adjustment constant (K) before step (c) (S130). As described above, the setting method of the adjustment constant K may be performed by the setting unit 210 of the blood pressure measurement system according to the present invention. The setting step (S140) may be performed only once for initial setting of the blood pressure measurement system described above, but may be performed at any time to maintain accuracy. For example, when it is found that the accuracy of the blood pressure value calculated by the blood pressure measurement method has deteriorated, the above-described setting step (S140) may be limitedly performed to correct the error. At this time, the setting step (S140) is (b) ) may be selectively performed after the vascular resistivity is obtained in step S120.

Then, the blood pressure value calculated in the above-described manner is output to a blood pressure output unit, for example, a display device so that the user can view it (S200).

Hereinafter, specific examples of blood pressure measuring methods by the blood pressure measuring system according to the present invention will be described with reference to FIGS. 4 to 12 .

First, referring to FIGS. 4 to 6 , in a specific embodiment of the blood pressure measuring system according to the present invention, a pressure sensor for measuring arterial pressure is applied as the above-described first sensor 110, that is, the arterial pressure measuring sensor, and a light emitting element ( The two optical sensors 121 and 122 including 120a) and the light receiving element 120b may be applied as the aforementioned second sensor 120, that is, the blood flow measurement sensor. Various types of pressure sensors, such as an air pressure sensor or a film-type pressure sensor, may be applied as the first sensor 110, that is, a pressure sensor. Measure.

The second sensor 120 described above may include two optical sensors 121 and 122, and as shown in FIG. 5 (a), the distance between blood flow measurement points (Δs: length of blood vessel between two blood flow measurement points ), when pulse waves are detected as shown in (b) of FIG. 5 at two points on the path through which the blood vessel A passes, a difference (Δt) is generated, from which the blood flow velocity (V=Δs/Δt) is obtained. and this blood flow velocity may be applied as a blood flow parameter (BM).

Alternatively, as in the example shown in FIG. 7 , PTT may be detected through the sensor unit 100 and a blood pressure value may be provided by applying the PTT as a blood flow parameter.

For example, the sensor unit 100 may include a first sensor 110 for detecting a cardiac output time parameter and an arterial pressure parameter, and a second sensor 120 for detecting an electrocardiogram (ECG) and a pulse wave. can An example of an arterial pressure measurement sensor, specifically, an air pressure sensor may be applied as the first sensor.

The above-described sensor unit may be implemented in the form of a wrist blood pressure monitor 10 by being installed on the wrist strap 131 surrounding the wrist as in the example shown in FIG. ), it may be implemented in the form of a brachial blood pressure monitor 20 by being installed.

More specifically, as in the example shown in FIG. 6, the wrist strap 131 is provided with an air bag 141 for artery compression and an air pump 142 for air supply of the air bag. The above air pressure sensor 110 may be provided in the air bag, and an exhaust valve 143 (Valve) for exhausting may be connected to the air bag 141.

Referring to FIG. 6 , a case 300A of the blood pressure output unit 300 may be mounted on the wrist strap 131, and the aforementioned air pump 142 may be built into the case 300A. and may be connected to the air bag 141 through an air filling passage 144.

Then, the air bag 141 is filled by the air pump 240, and the arterial wave is measured by the air pressure sensor 110 at a constant pressure. Accordingly, the arterial pressure parameter, cardiac output time parameter, and blood flow parameter may be detected by the pneumatic pressure sensor 110 . The air pressure sensor structure illustrated in FIG. 6 , for example, a structure in which the air pressure sensor is applied to an air bag may also be applied to the upper arm band 132 shown in FIG. 8 .

In order to detect the above-described electrocardiogram (ECG) and pulse wave, the second sensor 120 may include an electrocardiogram measuring unit (electrocardiograph) for measuring the electrocardiogram (ECG) and a pulse wave measuring unit for measuring the pulse wave. The second sensor 120, together with the first sensor 110, may be provided in the above-described sensor installation part, that is, a wrist strap or an upper arm band. As an example of the pulse wave measuring unit, a photoplethysmography (PPG) measuring device, which is an example of an optical sensor, may be applied.

Accordingly, an electrocardiogram may be detected by the electrocardiogram measurement unit, a pulse wave, that is, an optical artery wave may be detected by the pulse wave measurement unit, and the above-described PTT may be applied as a blood flow parameter.

Both ends of the wrist strap 131 or the upper arm band 132 may be intermittently connected by various detachable means such as buttons or Velcro.

9 illustrates arterial wave characteristic values that can be detected by the sensor unit. Referring to FIG. 9 , the pulse wave amplitude (A: height difference between the maximum maximum point and the minimum minimum point) and the time intervals between poles (B ₁ , B _{2 ,} B ₃ ), for example, the pulse cycle (B _{3 )} , etc. blood flow Examples of parameters can be applied. Poles refer to valleys and crests, for example, points at which a first derivative value is zero, and time intervals between neighboring poles refer to time intervals between neighboring valleys and crests or crests and valleys.

10 is a diagram illustrating a structure for detecting an arterial impedance wave, which is another example of a blood flow parameter. In a state in which an alternating current is applied to both ends 11 and 12, the inner two electrodes 21 and 22 measure voltage changes. A blood flow measurement sensor that measures and detects a human body impedance wave, that is, an arterial impedance wave, may be applied to a sensor unit for implementing the present invention.

Meanwhile, FIG. 11 is a graph showing the opening and closing time points of the semilunar valve of the heart and the shape of the arterial wave. In FIG. 11 , the cardiac output time parameter may be a time interval between an opening point and a closing point of the aortic valve in an arterial wave.

12 shows a period interval (Tfb) between a cardiac output wave (Wf) and a reflected wave (Wb) in an arterial wave (W). In FIG. 12 , cardiac output waves are generated when blood is ejected from the heart, and reflected waves are generated by reflection from the vascular resistance unit. The arterial wave is a mixture of the cardiac output wave and the reflected wave, and the time interval (Tfb) between the cardiac output wave and the reflected wave can be detected using the inflection point of the arterial wave. And, the time interval Tfb may be used as a blood flow parameter.

The above-described specific embodiments of the present invention can be implemented in a form worn on the wrist or upper arm, and easily acquires vascular resistivity and cardiac output time parameters at the wrist or other parts, and the height (altitude) difference between the measured part and the heart. Regardless of the blood pressure, the subject's blood pressure, that is, the blood pressure value at heart level, can be obtained more quickly and accurately.

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 in addition to the above-described embodiments without departing from the spirit or scope is those skilled in the art. It is self-evident to

Therefore, the foregoing embodiments are to be regarded as illustrative rather than restrictive, and thus the present invention is not limited to the foregoing description and may be modified within the scope of the appended claims and their equivalents.

100: sensor unit 110: first sensor
120: second sensor 130: sensor installation unit
131: wrist strap 132: upper arm band
141: air bag 142: air pump
200: blood pressure calculation unit 210: setting unit
300: blood pressure output unit (display device)

Claims (21)

a sensor unit for detecting a heart beat parameter in the body; and
and a blood pressure calculation unit configured to calculate a blood pressure value using the cardiac output time parameter. According to claim 1,
Through the sensor unit, it is possible to detect a blood flow parameter and an arterial pressure parameter together with the cardiac ejection time parameter; The blood pressure measurement system according to claim 1 , wherein the blood pressure calculation unit calculates the blood pressure value by using the cardiac ejection time parameter, the blood flow parameter, and the arterial pressure parameter. According to claim 1 or 2,
The blood pressure measuring system, characterized in that the sensor unit is a pressure sensor. According to claim 1 or 2,
wherein the sensor unit includes at least one sensor selected from the group consisting of a pressure sensor, a blood flow rate sensor, an optical sensor, an impedance sensor, an electrocardiogram sensor, an ultrasonic sensor, and a radar sensor. According to claim 2,
The blood pressure calculation unit; The blood pressure measuring system according to claim 1 , wherein a blood vessel resistivity is calculated from the blood flow parameter and the arterial pressure parameter, and the blood pressure value is calculated using the blood vessel resistivity and the cardiac ejection time parameter. According to claim 5,
The vascular resistivity is calculated by the following [Equation 1]; The blood pressure measurement system, characterized in that the blood pressure value is obtained by the following [Equation 2] to [Equation 4].
[Equation 1]

(R is vascular resistivity, AM is arterial pressure parameter, BM is blood flow parameter)

[Equation 2]

(BPmin is the diastolic blood pressure value, TMS is the sum of cardiac output parameters for a certain period of time, or (TM x pulse rate) or (TM x pulse rate during a certain period of time), K1 is the first adjustment constant)

[Equation 3]

(BPac is the systolic blood pressure value - the diastolic blood pressure value, TM is the cardiac output time parameter, and K2 is the second adjustment constant)

[Equation 4]

(BPmax is the systolic blood pressure value)
According to claim 6,
The blood pressure measurement system of claim 1, further comprising a setting unit for setting the first adjustment constant and the second adjustment constant. According to claim 2,
The blood flow parameter is; Blood pressure measuring system, characterized in that the blood flow velocity. According to claim 2,
The blood flow parameter is a blood pressure measurement system, characterized in that the time interval between the cardiac output wave and the reflected wave, which is one of the characteristic values of the arterial wave. According to claim 2,
The blood pressure calculation unit; The blood pressure measuring system according to claim 1, wherein a difference between a systolic blood pressure value and a diastolic blood pressure value at a region measured by the sensor unit is obtained as the arterial pressure parameter. According to claim 10,
the highest blood pressure value and the lowest blood pressure value; A blood pressure measurement system, characterized in that obtained by an oscillometric blood pressure measurement method. According to claim 1,
The blood pressure measuring system, characterized in that the sensor unit can be installed on one of the finger, wrist, wrist, forearm, and ear ball. As a blood pressure measurement method for calculating a blood pressure value using a biosignal detected from the body:
A blood pressure measurement method for calculating a blood pressure value using a cardiac output time parameter detected in a part of the body through a sensor unit. According to claim 13,
a parameter acquisition step of obtaining the cardiac output time parameter through the sensor unit; and
and a blood pressure calculation step of calculating the blood pressure value using the cardiac output parameter. According to claim 13,
(a) obtaining a blood flow parameter and an arterial pressure parameter along with the cardiac ejection time parameter through the sensor unit;
(b) calculating a blood vessel resistivity from the blood flow parameter and the arterial pressure parameter; and
and (c) calculating the blood pressure value using the vascular resistivity and the cardiac ejection time parameter. According to claim 15,
The step (a) is;
The method of measuring blood pressure, characterized in that obtaining a difference between a systolic blood pressure value and a diastolic blood pressure value at a region measured by the sensor unit as the arterial pressure parameter. According to claim 16,
The blood pressure measurement method of claim 1, wherein the systolic blood pressure value and the diastolic blood pressure value are obtained by an oscillometric blood pressure measurement method. According to claim 15,
The step (b) includes calculating the vascular resistivity using the following [Equation 1]; Step (c) comprises obtaining the blood pressure value using the following [Equation 2] to [Equation 4].
[Equation 1]

(R is vascular resistivity, AM is arterial pressure parameter, BM is blood flow parameter)

[Equation 2]

(BPmin is the diastolic blood pressure value, TMS is the sum of cardiac output parameters for a certain period of time, or (TM x pulse rate) or (TM x pulse rate during a certain period of time), K1 is the first adjustment constant)

[Equation 3]

(BPac is the systolic blood pressure value - the diastolic blood pressure value, TM is the cardiac output time parameter, and K2 is the second adjustment constant)

[Equation 4]

(BPmax is the systolic blood pressure value) According to claim 18,
The method of measuring blood pressure, characterized in that it further comprises a setting step of setting the first adjustment constant and the second adjustment constant before the step (c). According to claim 15,
The blood flow parameter is; A method for measuring blood pressure, characterized in that blood flow velocity. According to claim 15,
The blood flow parameter is a blood pressure measurement method, characterized in that the time interval between the cardiac output wave and the reflected wave, which is one of the characteristic values of the arterial wave.

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