JPH088907B2 - Electronic blood pressure monitor - Google Patents

Description

TECHNICAL FIELD The present invention relates to an improvement of an electronic blood pressure monitor.

(B) Conventional technology Conventionally, as electronic blood pressure monitors that employ the so-called vibration method, a cuff, a pressurizing pump that pressurizes the air inside the cuff (hereinafter referred to as pressurizing the cuff), and an air inside the cuff. Exhaust valve for decompressing air, pressure sensor for detecting air pressure in the cuff (hereinafter referred to as cuff pressure), and microcomputer (MPU)
Those equipped with are known. This MPU detects the pulse wave component from the output signal of the pressure sensor, calculates the pulse wave amplitude value from this pulse wave component, and calculates the systolic blood pressure value (SYS) and the diastolic blood pressure value (SYS) from the cuff pressure and the pulse wave amplitude value. DIA) is included.

In the conventional electronic sphygmomanometer described above, as a procedure for determining the systolic blood pressure value and the diastolic blood pressure value based on the pulse wave amplitude value and the cuff pressure, the one using a threshold value as described below is typical. .

The pulse wave is transmitted to the cuff by the volume fluctuation of the artery that occurs when blood tries to flow into the artery whose blood flow has been temporarily stopped by pressurization of the cuff when the pressure of the cuff is reduced at a constant slow speed. What is observed. And the pulse wave amplitude value Ap is
As shown in FIGS. 5 (b) and 5 (c), the cuff pressure Pc
It becomes larger with decreasing, and then gradually decreases after reaching the maximum value Ap max.

In the process of increasing the pulse wave amplitude value, the maximum pulse wave amplitude value Ap max
The cuff pressure at the time when the pulse wave amplitude value that is closest to the threshold value that is a predetermined ratio is determined as the systolic blood pressure value. Also,
In the process of decreasing the pulse wave amplitude value, the cuff pressure at the time when the pulse wave amplitude value closest to another threshold value that is a predetermined ratio of the maximum pulse wave amplitude value is observed is determined as the minimum blood pressure value (Fig. 5 ( a)
And FIG. 5 (c). In FIG. 5 (c), the maximum pulse wave amplitude value Ap m is used as the threshold value for determining the systolic blood pressure value.
The values of 60% of ax and 70% of the maximum pulse wave amplitude value Ap max are shown as the threshold values for determining the diastolic blood pressure value, respectively. (C) Problems to be Solved by the Invention The conventional electronic blood pressure monitor described above has a disadvantage that a systematic error occurs with respect to an accurate blood pressure value measured by the auscultation method. This will be described below with reference to FIGS. 6 (a) and 6 (b).

FIG. 6 (a) is a diagram showing the correlation between the auscultation-based systolic blood pressure value S _AUS (mmHg) and the vibration-based systolic blood pressure value S _OSC (mmHg) that were simultaneously measured for the same subject. is there.
The threshold value for determining the systolic blood pressure value S _OSC by the vibration method is set to 60% of the maximum pulse wave amplitude value Ap max.

In this case, for hypertensive patients, the maximum blood pressure value S
_OSC is measured low and for hypotensive patients, systolic blood pressure S _OSC is measured high. A straight line L's in FIG. 6 (a) is a straight line that approximates the correlation with the systolic blood pressure values S _OSC and S _AUS . This straight line L's is expressed by the following linear expression.

S _OSC ＝ as ・ SAUS ＋ bs …… (1) Specific values of as and bs are 0.91 (dimensionless) and
It is 11.2 (mmHg).

On the other hand, FIG. 6 (b) shows the auscultatory diastolic blood pressure value D _AUS (mmHg) simultaneously measured for the same subject,
It is a figure which shows the correlation of the minimum blood pressure value D _OSC (mmHg) by a vibration method. The threshold for determining the minimum blood pressure value D _OSC by the vibration method is set to 70% of the maximum pulse wave amplitude value Ap max.

Also in this case, for hypertensive patients, the minimum blood pressure value D
_OSC is measured low and, for hypotensive patients, diastolic blood pressure D _OSC is measured high. A straight line L'd in FIG. 6 (b) is a straight line that approximates the correlation with the minimum blood pressure values D _OSC and D _AUS . This straight line L'd is expressed by the following linear expression.

D _OSC = ad ・ D _AUS + bd (2) The specific values of ad and bs are 0.91 (dimensionless) and 7.5 (mmHg), respectively.

In the above explanation, systolic blood pressure values S _OSC and S _AUS , diastolic blood pressure values
Although the correlation equation between D _OSC and D _AUS is a linear equation, it may be represented by a higher-order equation such as a quadratic equation or more, and is generally represented by the following equations (3) and (4), respectively. .

S _OSC = fs (S _AUS ) (3) D _OSC = fd (D _AUS ) (4) The present invention has been made in view of the above problems.
An object of the present invention is to provide an electronic sphygmomanometer that eliminates an error that occurs when a blood pressure value is determined by the vibration method and can accurately measure the blood pressure value even in hypertensive and hypotensive patients.

(D) Means for Solving the Problems As means for solving the above-mentioned inconvenience, the electronic sphygmomanometer according to claim 1 of the present invention is a cuff and a pressure applying means for pressurizing the fluid in the cuff. A pressure means, a pressure reducing means for reducing the pressure of the fluid in the cuff, a pressure detecting means for detecting the fluid pressure in the cuff, a pulse wave component detecting means for detecting the pulse wave component, and the pulse wave component detecting means. A pulse wave amplitude value calculating means for calculating a pulse wave amplitude value from the detected pulse wave component, and a systolic blood pressure value and a diastolic blood pressure value based on the output signal of the pulse wave amplitude value calculating means and the output signal of the pressure detecting means. And a blood pressure value determining means for determining a blood pressure value determining means for determining the blood pressure value based on a correction equation represented by a linear expression of the highest blood pressure value determined by the blood pressure value determining means. Means are provided.

The electronic sphygmomanometer according to claim 2 of the present invention is a cuff, pressurizing means for pressurizing the fluid in the cuff, depressurizing means for depressurizing the fluid in the cuff, and the inside of the cuff. Pressure detecting means for detecting the fluid pressure, pulse wave component detecting means for detecting the pulse wave component, and pulse wave amplitude value calculating for calculating the pulse wave amplitude value from the pulse wave component detected by the pulse wave component detecting means A blood pressure value determining means for determining a systolic blood pressure value and a diastolic blood pressure value based on the output signal of the pulse wave amplitude value calculating means and the output signal of the pressure detecting means. It is characterized in that blood pressure value correcting means for performing a correction calculation on the minimum blood pressure value is provided based on a correction equation represented by a linear expression of the minimum blood pressure value determined by the means.

(E) Action When the electronic blood pressure monitor of the present invention performs a correction operation on the systolic blood pressure value determined by the blood pressure value determining means, the correlation equation (3) is used for the systolic blood pressure value S _AUS measured by the auscultation method. The systolic blood pressure value measured by the vibration method, corrected based on the solved formula S _AUS = gs (S _OSC ) ... (5)
Eliminate the systematic error from S _OSC .

When the correction calculation is performed on the minimum blood pressure value determined by the blood pressure value determining means, the correlation equation (4) is solved for the accurate minimum blood pressure value D _AUS measured by the auscultation method. _AUS = gd (D _OSC ) ... systolic blood pressure value measured by the vibration method, corrected based on (6)
Eliminate systematic errors from D _OSC .

(F) Embodiment An embodiment of the present invention will be described below with reference to FIGS. 1 to 3, 4 (a) and 4 (b).

First, the threshold value for determining the blood pressure value of the electronic sphygmomanometer according to this embodiment and the correction formula for the correction calculation will be described.

In the electronic sphygmomanometer of this embodiment, the threshold value for determining the maximum blood pressure value is 60% of the maximum pulse wave amplitude value Ap max, and the threshold value for determining the minimum blood pressure value is It is set to 70% of the maximum pulse wave amplitude value Ap max.

As the correction formula for the correction calculation, the following formula (5) is used for the systolic blood pressure value.

SYS = (S-bs) / as (5) as = 0.91 (6) bs = 11.2 (mmHg) (7) where SYS is the final systolic blood pressure value and S is It is the systolic blood pressure value (hereinafter referred to as the systolic blood pressure candidate value) determined by the blood pressure value determining means before performing the correction calculation. Expression (5) is a form obtained by solving Expression (1) for the systolic blood pressure value S _AUS .

On the other hand, the following linear expression (8) is adopted as the correction expression for the minimum blood pressure value.

DIA = (D-bd) / ad (8) ad = 0.91 (9) bd = 7.5 (mmHg) (10) where DIA is the final minimum blood pressure value and D is the blood pressure value. It is the diastolic blood pressure value (hereinafter referred to as diastolic blood pressure candidate value) determined by the means before performing the correction calculation. This formula (6) is also a form obtained by solving the formula (2) for the minimum blood pressure value D _AUS .

Next, a specific configuration of the electronic sphygmomanometer 1 of this embodiment will be described below with reference to FIGS. 2 and 3.

FIG. 2 is an external perspective view of the electronic sphygmomanometer 1 according to this embodiment. 2 is a cuff made of a band-shaped air bag. The cuff 2 is connected to the electronic sphygmomanometer body 4 via a flexible tube 3. On the upper surface of the electronic blood pressure monitor body 4,
A display device 5 including a liquid crystal display device, a power switch 6 and a measurement switch 7 are provided.

FIG. 3 shows a block diagram of the air system and the measuring circuit of the electronic sphygmomanometer 1. The cuff 2 has a tube 3 and pipes 8a, 8b, 8c.
Via the pressurizing pump (pressurizing means) 9, exhaust valve (depressurizing means)
10 and a pressure sensor (pressure detecting means) 11 are connected. The exhaust valve 10 is composed of two types of valves, a rapid exhaust valve and a slow exhaust valve. As the pressure sensor 11, a diaphragm type pressure converter using a strain gauge or a semiconductor pressure conversion element is used. In addition, the pressurizing pump 9 and the exhaust valve
10 is controlled by a micro computer (MPU) 14 described later.

The output signal of the pressure sensor 11 is amplified by the amplifier 12 and converted into a digital signal by the analog / digital (A / D) converter 13. The MPU 14 takes in the output signal of the pressure sensor 11 digitally converted by the A / D converter 13 at a constant cycle.
The MPU 14 has a function of detecting a pulse wave component from the output signal of the pressure sensor 11, a function of calculating a pulse wave amplitude value, a function of determining a systolic blood pressure candidate value and a diastolic blood pressure candidate value, a systolic blood pressure candidate value and a diastolic blood pressure candidate. It has a function of performing a correction calculation on the value, a function of controlling the pressurizing pump 9 and the exhaust valve 10, and the like. Further, the MPU 14 is connected to the display device 5 for displaying the maximum blood pressure value and the minimum blood pressure value, the power switch 6 and the measurement switch 7.

Next, the operation of the electronic sphygmomanometer 1 according to this embodiment will be described as follows.
Description will be given below mainly with reference to the drawings.

First, the cuff 2 is wrapped around the upper arm of the person to be measured, and the power switch 6 is turned on. When the power switch 6 is turned on, the MPU14
Determines whether the measurement switch 7 is turned on,
When it is not turned on, the determination process of is repeated and the process waits there (step ST (hereinafter referred to as ST) 1, see FIG. 1).

In ST1, when the measurement switch 7 is turned on, the MPU 14 operates the pressurizing pump 9 (ST2), and the cuff 2 is pressurized.
During this time, the MPU 14 takes in the cuff pressure Pc from the A / D converter 13,
It is determined whether the cuff pressure Pc has reached a predetermined cuff pressure (ST
3).

If ST3 determines that the cuff pressure Pc has reached the specified value, ST4
Then, the MPU 14 stops the pressurizing pump 9, opens the fine speed exhaust valve of the exhaust valve 10, and starts the fine speed exhaust of the cuff 2 (ST5).

In the next ST6, the timer T1 starts counting. This timer T1 uses the pulse wave component to calculate the pulse wave amplitude value Ap (n).
For determining the cycle for calculating
Set in seconds. In ST7, timer T2 starts counting. The timer T2 is for determining the sampling period in which the MPU 14 takes in the cuff pressure Pc (i) from the A / D converter 13. This cycle is set between 10 and 50 ms.

In ST8, the process waits until the timer T2 has timed up. If it is determined that the timer T2 has timed up, the process proceeds to ST9. ST
In 9, the MPU 14 takes in the cuff pressure data Pc (i) from the A / D converter 13. Furthermore, in ST10, these cuff pressure data Pc (i)
Thus, the pulse wave component value Pu (i) is detected.

As a means for detecting the pulse wave component, an analog means using a band filter is often used, but in this embodiment, a digital filter by the arithmetic processing of the MPU 14 is adopted. In the calculation processing of this digital filter, first, Pc (i) taken in the sampling data of this time is set as a variable x (i).

x (i) = Pc (i) (11) Next, the variable x (i
-1) and the other variable y (i-1), the value of the variable y (i) is calculated by the following equation (12).

αy (i) -βy (i-1) = x (i) -x (i-1)
(12) Further, by the other variable z (i-1) obtained in the previous sampling and the variables y (i), y (i-1),
According to the following equation (13), the variable z in this sampling
Calculate (i).

αz (i) -βz (i-1) = y (i) -y (i-1)
(13) z (i) obtained by the above equation is the pulse wave component value Pu (i) in this sampling.

Pu (i) = z (i) (14) The above α and β are usually set as follows.

α = 0.98 (15) β-0.95 (16) When i = 1, that is, when the digital filter is first processed, variables x (o), y (o) , And z (o) do not exist, these variables are set to zero as initial values in advance.

Furthermore, for the variable sequences x (i), y (i), and z (i), since only the previous value is used in the actual calculation, only the previous value is stored in memory in the actual calculation process. To save memory space.

When the pulse wave component value Pu (i) in ST10 is detected, the process proceeds to ST11, and it is determined whether or not the timer T1 has timed up. If the timer T1 has not timed up, return to ST7,
The detection of the pulse wave component value Pu (i) is continued.

If the timer T1 has timed up, proceed to ST12,
Pulse wave component value Pu detected during the current counting of timer T1
(I) The pulse wave amplitude value Ap (n) is calculated from the data string.
This Ap (n) calculation is based on the pulse wave component value Pu (i) data string during the counting of the current timer T1.
It is performed by extracting Pu min and taking the difference between them.

Ap (i) = Pu max-Pu min (17) In next ST13, it is determined whether or not the pulse wave amplitude value Ap (n) is increasing. If the pulse wave amplitude value Ap (n) is increasing, the flag F (indicating that the pulse wave amplitude value Ap (n) is increasing) is set to 1 in ST14, the process returns to ST6, and the next pulse wave is returned. Amplitude value Ap
(N + 1) is calculated.

When it is determined in ST13 that the pulse wave amplitude value Ap (n) is not increasing, the process proceeds to ST15. Then, the flag F is 1
It is determined whether or not (ST15).

If it is determined that F = 1 (the pulse wave amplitude value Ap (n) is increasing), proceed to ST16. If not, proceed to ST20.

In ST16, first, the flag F is set to zero. In the following ST17,
Pulse wave amplitude value Ap (n), which is the largest in the data string Ap
Extract max.

In ST18, the pulse wave amplitude value Ap (n) closest to the threshold value of 60% of the maximum pulse wave amplitude value Ap max is searched, and the corresponding cuff pressure Pc (i) is set as the systolic blood pressure candidate value S. To do. Continued ST19
Then, the systolic blood pressure candidate value S is corrected based on the equation (5) to obtain the systolic blood pressure value SYS. Then, returning to ST6, the pulse wave amplitude value Ap (n) data collection is continued.

Similar to the above, the processing from ST6 to ST12 is performed, and the pulse wave amplitude value Ap (n) is calculated. In ST13, pulse wave amplitude value Ap
Since (n) is in the process of decreasing, the process proceeds to ST13. Further, since the flag F is set to zero in ST16, it is determined to be NO in ST15 and the process proceeds to ST20.

In ST20, the pulse wave amplitude value Ap (n) is the maximum pulse wave amplitude value Ap m
Determine if it is less than 70% of ax. If this determination is NO, the process returns to ST6 to calculate the next pulse wave amplitude value Ap (n + 1).

If YES is determined in ST20, the process proceeds to ST21. ST21
Then, search for the pulse wave amplitude value Ap (n) that is the closest to the threshold value that is 70% of the maximum pulse wave amplitude value Ap max (however, after the maximum pulse wave amplitude value Ap max appears), and correspond to this. Cuff pressure Pc
Let (i) be the minimum blood pressure candidate value D. Subsequently, in ST22, the minimum blood pressure candidate value D is corrected based on the above equation (8) to obtain the minimum blood pressure value DIA.

Next, in ST23, the MPU 14 causes the display 5 to display the above SYS and DIA. Finally, in ST24, the MPU 14 gives a command to the exhaust valve 10, opens the quick exhaust valve, and quickly exhausts the cuff 2.
Finish the measurement.

FIG. 4 (a) shows the correlation between the systolic blood pressure value SYS measured by the electronic blood pressure monitor 1 of this embodiment and the systolic blood pressure value S _AUS simultaneously measured by the auscultation method. The plotted points in FIG. 4 (a) are on the straight line L _s represented by approximately SYS = S _AUS . From this, the systolic blood pressure value SYS
Eliminates systematic errors and is not conventionally measured lower for hypertensives and higher for hypotensives.

Similarly, FIG. 4 (b) shows an electronic blood pressure monitor 1 of this embodiment.
The correlation between the diastolic blood pressure value DIA measured by and the diastolic blood pressure value D _AUS simultaneously measured by the auscultation method is shown. The plotted points in FIG. 4 (b) also lie on the straight line L _D represented by approximately DIA = D _AUS . From this, the minimum blood pressure value
Systematic errors are eliminated and DIA is not measured lower for hypertensive patients and higher for hypotensive patients as before.

In the above embodiment, the threshold values for determining the blood pressure value are 60% and 70% of the maximum pulse wave amplitude value, but the threshold value is not limited thereto.

The values of the constants as and bs of the correction formula (5) and the constants ad and bd of the correction formula (8) are not limited to those shown here, and can be changed appropriately according to the change of the threshold value. Is.

(G) Effect of the Invention The electronic sphygmomanometer of the present invention is based on the correction equations represented by the respective linear equations of the systolic blood pressure value and the diastolic blood pressure value determined by the blood pressure value determining means, and the systolic blood pressure value and the diastolic blood pressure value, respectively. Since the blood pressure value correcting means for performing the correction calculation is characteristically provided in the above, the systematic error generated when the blood pressure value is determined by the vibration method is eliminated, and the blood pressure is accurately measured even in hypertensive and hypotensive patients. It has the advantage that the value can be measured.

[Brief description of drawings]

FIG. 1 is a flow chart for explaining the operation of the electronic sphygmomanometer according to an embodiment of the present invention, FIG. 2 is an external perspective view of the electronic sphygmomanometer, and FIG. 3 is a circuit diagram of the electronic sphygmomanometer. Block diagrams, FIGS. 4 (a) and 4 (b) are diagrams showing the correlation between the blood pressure value measured by the electronic sphygmomanometer and the blood pressure value measured by the auscultation method, and FIG. 5 (a). 5 (b) and 5 (c) are diagrams showing the principle of blood pressure value determination by the vibration method, and FIGS. 6 (a) and 6 (b) are conventional diagrams adopting the vibration method. It is a figure which shows the correlation of the blood pressure value measured by the electronic sphygmomanometer, and the blood pressure value measured by the auscultation method. 2: Cuff, 9: Pressure pump, 10: Exhaust valve, 11: Pressure sensor, 1
4: Microcomputer (MPU).

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Osamu Shirasaki 3 Tanaka Ishi Life Science Laboratory, Hanazono Nakamimon-cho, Ukyo-ku, Kyoto Prefecture (56) References JP-A-61-48339 (JP, A)

Claims (2)

[Claims] 1. A cuff, a pressurizing means for pressurizing a fluid in the cuff, a depressurizing means for depressurizing the fluid in the cuff, a pressure detecting means for detecting a fluid pressure in the cuff, and a pulse wave component. A pulse wave component detecting means for detecting, a pulse wave amplitude value calculating means for calculating a pulse wave amplitude value from the pulse wave component detected by this pulse wave component detecting means, and an output signal of this pulse wave amplitude value calculating means In an electronic sphygmomanometer comprising a blood pressure value determining means for determining a systolic blood pressure value and a diastolic blood pressure value based on the output signal of the pressure detecting means, in a linear expression of the systolic blood pressure value determined by the blood pressure value determining means. An electronic sphygmomanometer characterized in that blood pressure value correcting means for performing a correction calculation on a systolic blood pressure value based on a correction formula represented is provided. 2. A cuff, a pressurizing means for pressurizing a fluid in the cuff, a depressurizing means for depressurizing the fluid in the cuff, a pressure detecting means for detecting a fluid pressure in the cuff, and a pulse wave component. A pulse wave component detecting means for detecting, a pulse wave amplitude value calculating means for calculating a pulse wave amplitude value from the pulse wave component detected by this pulse wave component detecting means, and an output signal of this pulse wave amplitude value calculating means In an electronic sphygmomanometer comprising a blood pressure value determining means for determining a systolic blood pressure value and a diastolic blood pressure value based on the output signal of the pressure detecting means, in a linear expression of the diastolic blood pressure value determined by the blood pressure value determining means. An electronic sphygmomanometer characterized in that blood pressure value correcting means for performing a correction operation on a minimum blood pressure value is provided based on the correction formula shown.