KR20190105421A - apparatus and method for measuring blood presure based on PPG - Google Patents

Abstract

Disclosed are a blood pressure measuring method and a blood pressure measuring apparatus thereof. The blood pressure measuring method of the present invention comprises the steps of: measuring a pulse wave through photoplethysmography (PPG) in a part of a human body; distinguishing an incident wave by cardiac contraction and expansion through pulse wave analysis and reflected wave returning from a blood vessel rear branch point or terminal at the part of the human body; calculating a pulse return time (PRT) required for returning the reflected wave using waveforms of the distinguished incident wave and the reflected wave; and calculating a pulse pressure (PA) between high and low points among the pulse waves of the PPG and the PRT as a blood pressure (BP) indicator. According to the present invention, a progress of a blood pressure can be recognized by conveniently and continuously measuring the same without a separate operation for blood measurement of a wearer. Accordingly, the possibility of blood pressure management suitable for the wearer can be increased. According to an aspect of the present invention, an accurate blood pressure can be measured in spite of physical characteristics or variation factors of the wearer.

Description

Apparatus and method for measuring blood presure based on PPG}

Method of measuring blood pressure (BP) noninvasive by analyzing signals from photoplethysmography (PPG), which measures the pulse rate (Heart Rate, HR) of blood vessels by using a photoelectric device, and The present invention relates to a wearable blood pressure monitor (WBPM).

Cardiovascular Disease (CVD) is a major cause of death along with stroke, and the death toll is on the rise, but it is difficult to anticipate and costly for health care for prevention and care. to be.

Hypertension is considered to be the most important risk factor for cardiovascular disease and stroke and is strongly influenced by blood pressure levels. Along with absolute blood pressure, BPVariability (BPV) is also an important factor in these conditions and has been shown in many studies and clinical results.

Therefore, it is recognized that it is very important to continuously monitor blood pressure variations to minimize risks and to adjust risk factors from the beginning, and therefore, it is required to measure the blood pressure of patients who need attention continuously.

In terms of blood pressure measurement methods and devices currently in use, the most common noninvasive blood pressure measurement methods are the Auscultatory Method using the Inflatable Cuff and the Automated Oscillometric Approach. It is.

However, these methods have been applied to intermittent blood pressure measurement because of their inconvenient use at all times. Arterial Tonometry and Volume Clamp Techniques are being applied for Continuous BP Monitoring, but they are not sophisticated and somewhat uncomfortable for users.

Much research is underway to develop a wearable blood pressure monitor (wBPM) for continuous monitoring without cuffs, and some commercially available products.

There is also a blood pressure measurement method using pulse transit time (PTT), which is a method of estimating blood pressure by using an inverse relationship between blood pressure and pulse wave transmission time. In other words, as the blood pressure increases, the extension of the blood vessel wall decreases and accordingly the pulse wave delivery time decreases. On the contrary, when the blood pressure decreases, the blood pressure is measured based on the phenomenon that the extension of the blood vessel wall increases and the pulse wave delivery time increases. That's how. However, even in this method, an additional acquisition of the ECG signal is required to confirm the pulse wave propagation time.

The wBPM, currently being researched and developed, uses an electrocardiogram (ECG), which measures the electrical signal of the heartbeat, and an optical device that measures changes in blood flow using optical devices, between the high and low points of the photometer. Pulse Transit Time (PTT) or Pulse Wave Velocity, calculated from the time difference between electrocardiogram and photometer measurements based on pulse-to-valle pulse height or pulse pressure The mainstream method is to measure blood pressure by using PWV as an additional BP indicator.

Figure 1 shows the overall shape of the pulse wave that can be measured by the optical blood flow meter (PPG) in the wrist and the form of the pulsation component (AC componet) that is pure blood flow fluctuation except the base component (DC component) in the overall form.

Optical blood flow meters are initially limited to measuring the pulse wave to measure heart rate (HR) from changes in blood flow, but recently, the variation of the pulse wave itself using digital signal processing (DSP) technology is used. The pulsation component (AC component) and the base component (DC component) representing the RN may be classified and reanalyzed.

When using the optical blood flow meter, the pulsation component is affected by the pulse component of arterial blood, and can be used as a basic data for measuring the blood pressure as well as the pulse rate, and the second derivative of other body state information, such as a pulsation waveform. Vascular Aging information can be obtained from Second Derivative Waveform (SDPPG). Base components are usually affected by skin and tissues, venous blood, and non pulsatilecomponent of arterial blood.

The photosensor assembly of an optical blood flow meter used as a human body wear type typically uses green light, red light, and near infrared light (LED) as a light source. Photodiode (PD) is used to measure the change in reflected light intensity according to the blood flow, which is inversely related to the absorption coefficient.

On the other hand, the actual measurement shows a general and periodic change of the basal level due to breathing, but it is simplified here.

The optical blood flow meter reflects light toward human blood vessels, and the light receiving element measures the intensity of reflected and scattered light.In the systolic peak where blood flow increases due to heart contraction, blood pressure increases but light is absorbed by the blood so that the reflected light intensity It appears weak and the reflected light is strong during the relaxation period. In view of this, the output signal of the conventional optical blood flow meter is not reflected light intensity itself, but is inverted up and down (inversed PPG), so that the blood flow or blood pressure level is expressed in the form of pulse wave, high peak in the systolic phase and low valley in the diastolic phase. do. It can be seen that the signal amount display of a conventional photometer is based on this inverted form.

On the other hand, since the blood pressure is not zero even in the diastolic phase, the periodic amplitude change of the pulsating component occurs on the base level.

However, the conventional blood pressure measurement method, which consists of an electrocardiogram and an optical blood flow meter and mainly measures blood pressure using pulse wave transmission time (PTT) and pulse wave movement speed (PWV), has a human body for measuring an electrocardiogram when measuring blood pressure. Abnormal BP Variability is necessary because it requires two hands to touch the device at the same time to form part of the circuit, which is inadequate or inconvenient for Ambulatory BP Monitoring, and thus becomes an intermittent measurement method instead of constant monitoring. Or intensive monitoring of bioperiodic mutations.

In consideration of this problem, studies on blood pressure estimation using only the volume pulse wave while using the reflected wave arrival time (ΔTDVP) without the acquisition of an electrocardiogram signal have been conducted.

Blood pressure estimation using pulse wave propagation time (PTT) and blood pressure estimation using only volume pulse wave using reflected wave arrival time (ΔTDVP) are both simple and simple because they only estimate blood pressure as a single component of the extension of the vessel wall. It offers an easy way, but there are a number of issues that need to be addressed.

The pulse wave measurement, which is the basis of blood pressure measurement, needs to be accurate and precise. As the signal reaches the end of the human body, the signal weakens and there are many factors that confuse the signal. It can be a negative factor in signal interpretation.

Therefore, there is still a need for a blood pressure measuring device that can easily and continuously measure blood pressure without having to take a measurement operation.

Republic of Korea Patent Publication 10-2016-0026942: Portable blood pressure measuring device and method Korean Patent Publication 10-2006-0081166: Portable wireless terminal with a blood pressure measurement system using optical blood flow measurement signal Republic of Korea Patent Publication 10-2007-0101696: Blood pressure measurement method and apparatus using blood oxygen concentration and ECG Korea Patent Registration 10-0697211: Blood pressure measurement system and method using unrestrained pulse wave arrival time measurement

The present invention is to solve or alleviate the problems in the conventional blood pressure measurement described above, a blood pressure measurement method and a measuring device for continuously measuring and observing the blood pressure without the operation for a separate measurement in a human body wearable type The purpose is to provide.

An object of the present invention is to provide a measuring method and a measuring device capable of precise and effective blood pressure measurement, rather than inaccurate or rough blood pressure measurement.

According to an aspect of the present invention, it is possible to eliminate the inconvenience of measuring the blood pressure due to the mounting of the cuff or clamp, and to measure the measurement method and measuring device that can measure the accurate blood pressure despite the physical characteristics or variations of the wearer It aims to provide.

Body wear-type blood pressure measuring method of the present invention for achieving the above object is

In some parts of the body, pulse waves are measured by a photo blood flow meter (PPG),

Pulse wave analysis distinguishes the incident wave caused by cardiac contraction and the reflected wave returning from the back branch or end of blood vessel in the part of the body,

The pulse return time (PRT) is calculated by using the separated incident wave and the reflected wave waveform.

Pulse-to-Valley pulse high amplitude (PA = I _DIA -I _SYS ) or pulse pressure and PRT are used as BP indicators to calculate blood pressure. It is characterized by.

In this case, the pulse wave analysis may be performed through a waveform that differentiates the pulse wave.

In the present invention, the blood pressure is expressed by Equation 1 or Equation 1 obtained by multiplying the proportional constant a by the pulse pressure PA obtained through the measuring device by the program built into the measuring device and multiplying the proportional constant b by the PRT obtained through the measuring device. It can be calculated by the equation of 1 plus the constant e on the right side.

Equation 1 BP = a * PA + b * PRT

Alternatively, in the present invention, the blood pressure includes a green light in the irradiation light of the optical blood flow meter in order to include the human light absorbance as a blood pressure calculation factor, and has absorbance (GI) or reflectivity of the red light or infrared light (or reflectance). It can be obtained as a correction value of the blood pressure obtained through. The corrected value is calculated by Equation 2 or Equation 2 by adding constant e to the right side of Equation 2 by adding the blood pressure obtained from the pulse pressure and the PRT as the index by multiplying the absorbance or reflectance of green light by the proportional constant c. It may be.

(Formula 2) BP = a * PA + b * PRT + c * GI

Alternatively, in the present invention, the blood pressure is a ratio between the pulse wave level and the pulse pressure of the valley portion of the optical blood flow meter or the ratio of the pulse wave level of the valley portion and the peak portion of the peak portion to include the influence of the pulse wave base as the blood pressure calculation factor. (IR = I _DIA / I _SYS ). The corrected value may be obtained by Equation 3, which is obtained by multiplying the ratio obtained by multiplying the ratio and the proportional constant d by the blood pressure obtained by the pulse pressure and the PRT, or by Equation 3 with the constant e added to the right side.

Equation 3 BP = a * PA + b * PRT + d * IR

In the present invention, when considering the pulse pressure (PA), PRT, GI, IR (I _DIA / I _SYS ) as the relevant factor (element) of the blood pressure in general, the blood pressure is a constant on the right side in the following Equation 4 or Equation 4. It can be represented by an equation plus e.

(4) BP = a * PA + b * PRT + c * GI + d * IR

Likewise, in the present invention, the blood pressure may be obtained by adding a value obtained by multiplying a measured value related to this factor by a proportional constant corresponding thereto to the blood pressure obtained by the pulse pressure and the PRT as an indicator to include other effects as the blood pressure calculation factor.

For example, in the present invention, in order to correct the effect of the external light entering by the gap between the body and the light receiving element, the sensing light intensity of the light receiving element is checked and subtracted or the difference value is multiplied by the proportional constant in the absence of the irradiation light. Can be obtained.

In addition, the distortion of the PPG pulse wave due to the operation of the wearer of the measuring apparatus may be excluded by linking the change of the PPG pulse wave generated by the movement of the user with the motion signal of the accelerometer having three-dimensional degrees of freedom.

The proportional constants mentioned above measure blood pressure and related factors (PA, PRT, GI, IR) multiple times for various measurement subjects and substitute them in the above formula to derive the most appropriate proportional constant value. Can be obtained as At this time, the blood pressure is measured by another precise blood pressure monitor, and at the same time by measuring the relevant factors with an optical blood flow meter such as that adopted in the blood pressure monitor of the present invention, put these values into a calculation formula to make a plurality of equations and simultaneously It goes through the process of finding proportional constant that can be satisfactorily satisfied.

In the above, blood pressure is not distinguished from systolic blood pressure, diastolic blood pressure, and average blood pressure, but in principle, all of them can be derived in the same way, so it is not distinguished here and is simply expressed as blood pressure (BP).

This process can be accomplished through statistical techniques such as multivariate statistics techniques and computer simulations.In recent years, artificial neural networks that embody these techniques through machine learning or deep learning based on this type of data. It can also be derived by having the application program review the measured data (blood pressure and related factors) that are test data.

Measuring device of the present invention for achieving the above object

The optical blood flow meter (PPG) which can measure a pulse wave is provided, and this optical blood flow meter is a red or near-infrared light source which can irradiate light toward a body in contact with a body, and a light reflected from a body A light receiving element is provided, and the incident wave and the reflected wave are distinguished by analyzing the pulse wave formed by the detection signal of the light receiving element, the PRT is detected using the peak signal of each wave, and the pulse pressure PA is multiplied by the first coefficient and the PRT And a processor and a program for deriving a blood pressure value through a calculation process including multiplying and summing a second coefficient.

The program for deriving the blood pressure value through the measurement result of the optical blood flow meter in the measuring device of the present invention is based on one of the above-described Equations 1 to 4 or an equation in which the constant e is added to the right side of these equations. It may be.

At this time, the proportional constants and constants (a, b, c, d, e) measure blood pressure and related factors (PA, PRT, GI, IR) several times for various measurement subjects, Substituting the most appropriate proportional constant values by substituting them, the blood pressure was measured by another precise sphygmomanometer, and at the same time the relevant factors were measured by an optical blood flow meter, and the process of finding the proportional constant was artificial neural network. network) algorithm may be applied through a program.

The measuring device of the present invention may be provided with a communication device to transmit and record the measured blood pressure value to a separate server in a wireless manner through a communication network.

The measuring device of the present invention may be provided with a storage and display device for recording and storing the measured blood pressure values continuously for at least a predetermined period so as to grasp the change trend (pattern).

The measuring device of the present invention compares the measured blood pressure value or the recent change in blood pressure value with a predetermined criterion to warn the wearer with an alarm device or show it as a display device, and to warn or display the medical institution or guardian in charge through a communication device. It can be configured to deliver.

The measuring device of the present invention has a short near infrared band light source for measuring pulse pressure and PRT as a related factor for deriving blood pressure values, and reflects attenuation of light in the short near infrared band due to skin color of the wrist part to be measured. In order to measure the reflectance of the wrist portion to the green light whose reflectivity is greatly influenced by the skin color or the like, it may have a green light source.

In this case, a separate light receiving element for the green light source may be disposed in the blood pressure measuring device, but the light of the red light or the near infrared light source and the light of the green light source may be time-divisionally separated from each other by hardware or a program in the blood pressure measuring device. The light receiving device may be configured to distinguish whether the detection light is green light, red light or near infrared light.

According to the present invention, it is possible to recognize the trend of blood pressure by continually measuring and observing blood pressure conveniently and easily without a separate operation for measuring the wearer's blood pressure, thereby increasing the possibility of appropriate blood pressure management to the wearer.

According to the present invention, it is possible to perform accurate and effective blood pressure measurement, but not inaccurate or coarse blood pressure measurement when measuring blood pressure while performing continuous measurement.

According to one aspect of the present invention, it is possible to eliminate the inconvenience of measuring blood pressure due to the mounting of the cuff or clamp, and to measure the accurate blood pressure despite the physical characteristics or variation factors of the wearer.

1 is a graph showing the overall shape of the pulse wave that can be measured by the optical blood flow meter (PPG) on the wrist and the pulsation component (AC componet) which is the pure blood flow fluctuation except the base component in the overall form;
2 is a conceptual diagram of a box-shaped configuration showing a schematic configuration of an embodiment of the present invention;
Figure 3 is a bottom view showing the bottom of an embodiment of the blood pressure measuring device of the present invention based on an optical blood flow meter,
4 is a conceptual cross-sectional view schematically showing a cross section taken along line AA ′ of FIG. 3;
Fig. 5 is a graph showing an example of the form of one period of the pulsating component of the pulse wave in the upper arm (forearm), the wrist, the finger, and the form in which the incident wave and the reflected wave are divided;
6 is an explanatory diagram showing the degree of penetration of light of each wavelength band to a body part in the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

2 is a schematic conceptual view showing a schematic configuration of an embodiment of the present invention, Figure 3 is a bottom view showing the bottom of an embodiment of the blood pressure measuring device of the present invention based on an optical blood flow meter, Figure 4 is a AA 'line of Figure 3 Conceptual cross-sectional view schematically showing the cross section cut along.

Referring to FIG. 2, the blood pressure measuring apparatus includes three light emitting diodes corresponding to three light sources 30: 31, 32, and 33 and scatters and reflects light after the light from the light sources 30 is irradiated onto the body part. Two photodiodes as a light receiving element 20 for generating an electrical signal, two transimpedance amplifiers (TIA: 11) arranged in a path for acquiring a signal for output signal processing of the light receiving element 20, a programmable gain amplifier (Programmable Gain Amplifier (PGA) 13), Analog-to-Digital Convertor (ADC: 15).

The converted output signal through these is input to the processor 70 and undergoes a process of obtaining information for blood pressure measurement from the pulse wave waveform. The processor 70 may be divided into a digital signal processor (DSP) 73 and a micro controller unit (MCU) 71. The processor 70 also controls a controller or driver (LED driver) 17 that emits a light signal by using a light emitting diode, and a storage device (memory) 90 and a communication device 80 are connected to the processor.

Although not shown, the processor performs operations such as turning on the light source, classifying the output of the light-receiving element, analyzing waveforms for calculating blood pressure, and substituting the blood pressure-related factors obtained through the predetermined calculation equation.

Referring to FIG. 3, the optical sensor assembly 10 having the light source 30 and the light receiving element 20 is not directly shown, but is located on the bottom of the blood pressure measuring device, similar to the wrist watch. Three light sources 30 are installed in the optical sensor assembly 10, and two light receivers 20 are installed on each of the left and right light sources.

In the optical sensor assembly 10, the light source 30 includes a green light source 31 in the 530 nm wavelength range, a red light source 32 in the 660 nm wavelength range, and a short near infrared light source 33 in the 940 nm wavelength range. The light receiving elements 20 on both the left and right sides use a silicon (Si) wafer-based photodiode.

Of course, according to the embodiment, the light source may be provided with two green light sources and near infrared light sources, or only two of the green light sources and the red light sources, and the near infrared light sources may also be light sources of different wavelength bands. Such selection is a common criterion for detecting blood flow most accurately and clearly, but in reality, consideration may be made for development ease and commercialization, such as cost, device stability, and degree of commercialization.

Placing the light receiving element 20 on both sides of the light source 30 may increase the total signal by increasing the number so that the detection ability of the light receiving element may not be sufficient. It makes sense. In particular, considering that the pulse of the upper arm, which is used for the accurate measurement of blood pressure in general, is much stronger than the pulse of the wrist and the signal is clear, it is meaningful as such an operation to increase the signal to noise ratio or signal accuracy.

In addition, there may be a slight change in the wearing position when the blood pressure measuring device is worn in the form of a wrist band or a watch, and the artery position may be disposed so as not to match the position of the light source 30 and one light receiving element 20. The problem may be given to cover the problem so that even one light receiving element 20 can receive the reflected and scattered light signals well.

A hemispherical convex lens 60 is formed on the LED constituting the red light source 32 used as a light source in the center to increase the focusing speed of the light irradiated toward the body part, and the light drawn from the outside on the photodiode as the light receiving element 20. In order to focus, a DOE (diffractive optical elements) lens 50, which is a kind of condenser lens, is installed. The photodiode is installed in a larger area than the LED in order to increase the amount of received light, and when the hemispherical convex lens 60 is installed thereon, the height is considerable, so that the DOE lens 50 is installed because it is difficult to shorten the blood glucose measurement device. It is.

The blood pressure measuring device in the form of a wrist band or wrist watch adds other functions in addition to the optical noninvasive continuous vital sign monitoring function, for example, a digital thermometer or a 3D accelerometer function. You can monitor other physical conditions, physical condition of the body, falls, etc., and correlate it with Vital Sign Trend to detect Unexpected Fluctuation and alert the wearer through the warning device. It can also serve to alert the guardian or medical personnel and provide attention signals through the embedded communications device and the surrounding communications network.

Looking at the blood pressure measurement method using the blood pressure measuring device based on the optical blood flow meter, first, the blood pressure measuring device is filled in the cuff of the blood pressure measuring object and the power is turned on to activate the optical blood flow measuring function. As a result, the pulse wave is measured using a cuff of the wrist by irradiating light to the cuff of the light source continuously or at a short time period (so that the measurement can be made longer than the pulse period). Acquire.

This measurement uses a red or near-infrared light source that can penetrate relatively deep into the human body and send a significant amount of reflected or scattered light to the light-receiving device, which can relatively clearly represent and reflect changes in arterial blood flow in the pulse wave signal.

Analysis of the pulse wave of such a blood pressure measuring device shows the time between peaks and peaks, the difference in the amount of signal between the peak representing the blood pressure elevated by the heart contraction and the valley lowered by the cardiac relaxation, the time between the incident wave and the reflected wave peak at the measurement position. Can be found. For this purpose, the parts by the base are not important in the pulse wave analysis, so that DC and AC can be distinguished, and processing and analysis showing separate reflection and incident waves from AC can be performed, and the differential wave form of the pulse wave for the changed part is obtained and analyzed. Can be done. For this processing, several known digital signal processing (DSP) techniques can be used.

For example, when a light receiving element receives an optical signal and outputs an electric signal, the transimpedance amplifier (TIA) circuit is first used to remove noise and to convert and amplify the current signal of the light receiving element into a voltage signal. A programmable gain amplifier (PGA) offset value (corresponding to bias) and an analog-to-digital converter to analyze the level of the DC component from the signal of the signal and remove the DC component from the PPG signal. Convertor: In order to take full advantage of the resolution of the ADC, the gain can be stored in memory and reflected in the blood pressure calculation.

Pulse hight (PA = I _DIA- I _SYS ) of the pulse wave obtained from the optical blood flow meter (Peak-to-Valley) is called the pulse pressure and is the most important indicator of the BP indicator. Pulse pressure is commonly used as one of the most important factors for calculating blood pressure, and typically, when the pulse pressure is high, the blood pressure will tend to be high.

5 shows the shape of the peak portion of the total pulse wave (composite wave due to the superposition of the incident wave and the reflected wave) on the upper arm (forearm), wrist, and finger, and the incident wave (simple peak with a large peak) and the reflected wave. An example of the form divided by (the simplest waveform with the smallest peak) is shown. The pulse return time (PRT) is calculated using the separated incident wave and the reflected wave waveform.

Given that PTT of ECG and PPG can be used to predict blood pressure, both PTT and PRT (time between compressor incident and reflected wave peaks) are largely dependent on the stiffness or elasticity of blood vessels (arteries). Assuming proportional relations, the possibility of calculating blood pressure by analyzing the PPG waveform without ECG is derived.

For example, in the conventional blood pressure measurement using ECG, if D is the distance between the heart and the blood pressure measurement position (mainly the upper arm), the pulse wave propagation speed (PWV) is obtained by dividing this distance D by PTT. It increases when the arterial stiffness or stiffness is about 6m / sec and 14m / sec in the 60s. In simple theory, PRT = 2d / PWV = 2d / D * PTT, which can be proportional to PTT and inversely related to PWV.

Based on this possibility, data were obtained through experiments, which directly confirmed the association between PTT and PRT.

When the PRT is shortened in the realistic measurement range and approaches 1/3 of the heartbeat interval, the incident and reflected wave waveform overlaps, which increases blood flow resistance and consequently increases blood pressure.

Therefore, in consideration of the above, the basic expression of blood pressure can be obtained by using pulse pressure and PRT as basic blood pressure factors (factor).

In this embodiment, the green light source is operated together with the red light source or the short near infrared light source to measure the light absorption due to the skin color at the cuff region, and also calculate the mutual ratio of DC component and AC component in the pulse wave waveform. This value can be used to compensate for variations in blood pressure caused by factors that affect the base components of the pulse wave, such as skin, muscle tissue, blood vessel walls, and body fluids in the wrist. This correction is intended to offset the effect of the individual physical characteristics on the measurement of conventional photometers so that accurate blood pressure values can be obtained.

That is, the present invention is based on an optical blood flow meter, and the light irradiated to the body is absorbed, reflected or scattered at each part of the body so that a substantial portion of the reflected and scattered light is input to the light receiving device. Therefore, the light input to the light receiving element may vary depending on the physical characteristics of the subject.

The blood pressure measuring device of the present invention is produced to measure blood pressure universally, and when it is not tailored to individual characteristics, the measured and calculated blood pressure values are not measured without considering the physical characteristics of the subject. May not be able to indicate the correct blood pressure of the individual.

6 is a conceptual diagram for explaining that the penetration depth or the light absorption degree of the layer structure of the human body part for each wavelength of light is different.

Referring to FIG. 6, in order to take into account individual differences, measurement using the green light absorbed relatively well by body tissues can be used as a reference that also shows the physical light absorption (IG) of the individual to be measured, and reflects this in the blood pressure calculation. Do it. That is, the greater the light absorption, the greater the absorption of red or near-infrared light, and the light input to the light-receiving element as reflected light or scattered light will be weakened and eventually increase the level of signal level (upside down) displayed by the optical blood flow meter. This effect should be subtracted from the calculation of blood pressure so that the blood pressure value is lowered and displayed.

Referring back to FIG. 1, if the measurement target is a large and fat person, the amount of light entering the body from the light source, reflected or scattered, and entering the light receiving element will be reduced, and the base level (DC level) will be increased in the signal amount. The IR (I _DIA / I _SYS ) value will also be higher, and the measured blood pressure may be higher than the actual value. Where I _DIA is the signal value strength of the diastolic _phase , I _SYS is the signal value strength of the systolic phase, and IR value is the ratio between them. Therefore, in this case, considering the base component, the blood pressure value should be lowered and displayed as in the case of reflecting light absorption.

Reflecting all the above-mentioned, the blood pressure calculation formula will be the same as the equation (5) in which the constant e is added to the right side of the equation (4) or (4) in the basic equation, such as the above equation (1).

Equation 5 BP = a * PA + b * PRT + c * GI + d * IR + e

On the other hand, in consideration of the above-mentioned statement regarding the proportional constant, for example, the proportional constant a will be positive because the higher the blood pressure, the higher the normal blood pressure, and the higher the stiffness, the higher the blood pressure, but the higher the vascular stiffness, the smaller the scaffold constant. b will be a negative value. If the green light absorption (IG) is high or the specific gravity (IR) of the base is high, the blood pressure may be higher than the actual value. Therefore, the values of the proportional constants c and d are generally negative. would.

Such a blood pressure calculation formula is built into the blood pressure measuring apparatus of the present invention as a kind of program, and when the pulse wave analysis result and the green light absorption measurement result are put into the calculation formula, the blood pressure value is calculated by a predetermined proportional constant or constant.

In this case, the proportional constant or constant of the calculation formula is used to measure blood pressure and related factors (PA, PRT, GI, IR) multiple times for various measurement subjects and substitute them in the above formula to derive the most appropriate proportional constant value. Can be obtained in such a way. At this time, the blood pressure is measured by another precise blood pressure monitor, and at the same time by measuring the relevant factors with an optical blood flow meter such as that adopted in the blood pressure monitor of the present invention, put these values into a calculation formula to make a plurality of equations and simultaneously It goes through the process of finding proportional constant that can be satisfactorily satisfied.

This process can be accomplished through statistical techniques such as multivariate statistics techniques and computer simulations.In recent years, artificial neural networks that embody these techniques through machine learning or deep learning based on this type of data. The algorithm application program can be derived by reviewing (learning) the measured data (blood pressure and related factors) which are the test data.

Through this process, the present invention justifies the idea or paradigm that only PPG can be used to calculate blood pressure by optical method, and influences on the blood pressure value of secondary elements such as light absorption or base in using optical method. Was removed using appropriate standardization.

In this case, the artificial neural network used is a logical foundation in artificial intelligence that obtains a method for solving a problem by deep learning. Recently, the neural network is developed and a detailed description thereof will be omitted.

According to the embodiment, unlike the above embodiment, the basic pressure equation (BP = a * PA is calculated so that the blood pressure is calculated by multiplying the pulse pressure obtained through the blood pressure measuring device by the proportional constant a and multiplying the PRT obtained by the measuring device by the proportional constant b. + b * PRT), or a formula that includes only the effects of human light absorbance on these basic equations (BP = a * PA + b * PRT + c * GI), or uses pulse wave The formula (BP = a * PAP + b * PRT + d * I _DIA / I _SYS ) can be used to reflect only the influence of the base, and this formula is also built in the blood pressure measuring apparatus of the present invention in a form of a built-in program. When pulse pressure (PA), PRT, GI, IR (I _DIA / I _SYS ), etc. are measured as necessary elements (factors) installed, the built-in processor of the blood pressure measuring device puts the measured value into a calculation formula to calculate blood pressure. The measuring device can be made.

The present invention has been described above by way of limited embodiments, which are only illustratively described to help understanding of the present invention, and the present invention is not limited to these specific embodiments.

Therefore, one of ordinary skill in the art to which the present invention pertains may make various modifications or applications based on the present invention, and such modifications and applications belong to the appended claims.

10: Optical Sensor Assembly 11: Transimpedance Amplifier (TIA)
13: Programmable Gain Amplifier (PGA) 15: Analog-to-Digital Converter (ADC)
17: LED driver 20: light receiving element
30: light source 50: DOE lens
60: hemispherical convex lens 70: processor
80: communication device 90: memory

Claims (8)

Pulse wave is measured at the body part using a photo blood flow meter (PPG),
Pulse wave analysis distinguishes the incident wave caused by cardiac contraction and the reflected wave returning from the back branch or end of blood vessel in the body part,
The pulse return time (PRT) is calculated by using the separated incident wave and the reflected wave waveform, and
Calculation of blood pressure using pulse hight (PA = I _DIA- I _SYS ) and PRT as a BP indicator among pulse waves measured by the optical blood flow meter Blood pressure measuring method, characterized in that. The method of claim 1,
The blood pressure calculation may be performed using at least one of the following formulas 1 to 4, including multiplying the pulse pressure PA obtained through the optical blood flow meter by multiplying the proportional constant a and multiplying the PRT by the proportional constant b; Blood pressure measurement method characterized by using the addition of the constant e to the equation.
Calculation 1: BP = a * PA + b * PRT
Calculation 2: BP = a * PA + b * PRT + c * GI
Calculation 3; BP = a * PA + b * PRT + d * IR (I _DIA / I _SYS )
Calculation 4: BP = a * PA + b * PRT + c * GI + d * IR (I _DIA / I _SYS )
In this case, GI is the light absorption or light absorption rate for green light,
IR is the ratio of the base level (DC level) to the total amount of the signal measured as I _DIA / I _SYS , where I _DIA is the signal value strength of the diastolic _phase and I _SYS is the signal value strength of the systole. The method of claim 2,
The proportional constants are measured by a blood pressure measuring device that has been verified a plurality of times against a plurality of measurement subjects, and the related elements (PA, PRT, GI, IR) are measured by the optical blood flow meter and substituted into the calculation formula. Get the formula of
Obtained by calculating a value of proportional constants that minimizes the deviation between the measured blood pressure value on the left side and the calculated value on the right side for all of the plurality of equations, or
Blood pressure measurement method characterized in that it is derived through the application of artificial neural network (artificial neural network) learning using the plurality of formulas as a machine learning or deep learning data. An optical blood flow meter (PPG) capable of measuring pulse waves is provided, and the optical blood flow meter is
A red light source or a near-infrared light source capable of irradiating light toward the body part, and a light receiving element capable of sensing light reflected from the body on a side in contact with the body part,
The pulse wave PA is analyzed by analyzing the pulse wave formed by the detection signal of the light receiving element, the incident wave and the reflected wave are distinguished, the PRT is detected using the peak signal of the incident wave and the reflected wave, and a first coefficient is applied to the pulse pressure PA. A blood flow meter-based human body comprising a processor and a program for calculating a blood pressure (BP) through a calculation process including multiplying (proportional constant) and multiplying and adding a second coefficient (proportional constant) to the PRT. Wearable blood pressure measuring device. The method of claim 4, wherein
The optical blood flow meter is provided with a green light source for measuring the reflectance of the wrist portion to the green light whose reflectivity is greatly affected by the skin color, in order to reflect the attenuation of light in the short near infrared band due to the skin color of the wrist portion of the measurement target,
The human body type blood pressure according to the present invention is that the light of the red light source or the near infrared light source and the light source of the green light source are time-divisionally separated from each other to emit light. Measuring device. The method according to claim 4 or 5,
The blood pressure calculation may be performed using at least one of the following formulas 1 to 4, including multiplying the pulse pressure PA obtained through the optical blood flow meter by multiplying the proportional constant a and multiplying the PRT by the proportional constant b; Human blood pressure measuring device based on the optical blood flow meter, characterized in that using the addition of a constant e to the equation.
Calculation 1: BP = a * PA + b * PRT
Calculation 2: BP = a * PA + b * PRT + c * GI
Calculation 3; BP = a * PA + b * PRT + d * IR (I _DIA / I _SYS )
Calculation 4: BP = a * PA + b * PRT + c * GI + d * IR (I _DIA / I _SYS )
In this case, GI is the light absorption or light absorption rate for green light,
IR is the ratio of the base level (DC level) to the total amount of the signal measured as I _DIA / I _SYS , where I _DIA is the signal value strength of the diastolic _phase and I _SYS is the signal value strength of the systole. The method according to claim 4 or 5,
A storage device and a display device for recording and storing the measured blood pressure values continuously for at least a predetermined period so as to identify a change pattern (pattern);
Optical blood flow meter based human blood pressure measuring device, characterized in that the communication module is provided to transmit and record the measured blood pressure value and blood pressure change to a separate server in a wireless manner through a communication network. The method of claim 7, wherein
The measured blood pressure value or the change in blood pressure value is compared with a predetermined criterion to warn the wearer by an alarm device or to show it on the display device, and to transmit a warning or indication to a medical institution or guardian through the communication module. Human blood pressure measurement device based on the optical blood flow meter.

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