JP3529886B2 - Blood pressure cuff - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cuff for a blood pressure monitor, and more particularly to a cuff used for a non-invasive blood pressure monitor.

[0002]

2. Description of the Related Art A non-invasive blood pressure monitor in which a cuff that compresses an artery is wound around a subject's upper arm is known. The blood pressure determination method of this type of blood pressure monitor is an oscillometric method or Korotkoff sound. Method, impedance method, etc., but oscillometric method is mainly used clinically. A sphygmomanometer that employs such an oscillometric blood pressure determination method is disclosed, for example, in Japanese Examined Patent Publication No. 6-28637.

The sphygmomanometer disclosed in this publication is attached to the upper arm of a subject and has a cuff having an air bag for injecting air to press the artery, and the pressure drop and pulse that change in the air bag of the cuff. The pressure sensor that detects the superimposed pressure with the pressure, the measurement unit that converts the detection value of this pressure sensor into a digital signal, and the cuff pressure detection signal output by this measurement unit as the input signal The digital data processing unit for obtaining the value and the display unit for displaying the highest and lowest blood pressure values calculated by the digital data processing unit have a basic configuration.

In the sphygmomanometer configured as described above, the maximum and minimum blood pressures are determined by the digital data processing unit from the change in the amplitude of the pulse pressure oscillation in the process of lowering the pressure in the cuff. The cuff used in the blood pressure determination method based on the oscillometric method has the following problems.

[0005]

That is, in the blood pressure determination method, an ideal method is to capture a local area of the subject's artery and measure the lateral pressure of the blood vessel wall, as represented by intra-arterial catheterization. is there. However, in the blood pressure determination method based on the oscillometric method described above, the pressure change in the air bag of the cuff wrapped around the subject's upper arm is detected, and this is used for blood pressure determination. In this case, the pulse pressure appeared or the determination of the minimum blood pressure was unclear.

The cause of this is that in the blood pressure determination method in the oscillometric method, the average pulsation of the artery across the cuff is detected, and the pulsation is the displacement of the arterial wall of the brachial artery due to the heartbeat. Is propagated as a displacement of the skin surface, and further the displacement of the skin surface changes the air volume in the air bag of the cuff, and this volume change is detected as a pressure change in the cuff, and as a result, The displacement of the arterial wall is converted into a pressure change in the cuff.

However, in such a method, the amount of displacement of the arterial wall is measured by using the air in the air bag of the cuff as a medium, so that the cuff is affected by in vitro effects such as compression characteristics and damping characteristics of the air. The pulse pressure waveform obtained from inside could not accurately capture the arterial wall displacement. This also means that during blood pressure measurement, the Korotkoff sound component having a frequency component higher than the pulse pressure waveform should appear superimposed on the pulse waveform during the cuff depressurization process from the systolic blood pressure to the diastolic blood pressure. However, in the cuff pulse pressure waveform of the oscillometric method, since air is used as the medium, it is not possible to propagate changes in high frequency components such as Korotkoff sounds, and as a result,
It seems that such components do not appear clearly.

That is, in the conventional blood pressure determination method using the oscillometric method, the cuff is wound around a wide range of the brachial artery, which is the measurement site of the subject, and the pulse pressure wave vibration is detected by changing the pressure within the cuff pressure. , Does not accurately reflect the local arterial pressure of the arterial wall, which is the ideal blood pressure determination method,
For this reason, a pulse pressure wave appears at a cuff pressure higher than the systolic blood pressure, and because the pulse pressure wave propagates through air as a medium, it is affected by frequency propagation due to the compressibility and damping characteristics of air, and Korotkoff sound is generated. Inconveniences such as hindering the propagation of

The present invention has been made in view of such conventional problems, and an object thereof is to accurately measure blood pressure by directly measuring a local displacement of an arterial wall. It is to provide a cuff for a blood pressure monitor that becomes possible.

[0010]

In order to achieve the above object, the present invention relates to a blood pressure monitor cuff which is attached to a main part of a subject and injects air to compress an artery. A hard curved plate held between outer cloths, a locking fastener fixed to the outer surface of the outer cloth, an air bag fixedly provided on the inner peripheral side of the inner cloth, and the air bag, And an optical distance sensor installed opposite to each other between the outside. The optical distance sensor can be composed of a reflector provided inside the air bag and a light receiving and emitting element provided outside the air bag. Further, the optical distance sensor may include a pair of light receiving and light emitting elements, one of the elements may be provided inside the air bag, and the other of the elements may be provided outside the air bag. The air bag can be composed of a transparent bag body and a lattice-like reinforcing fiber integrally incorporated in the bag body.

[0011]

According to the sphygmomanometer cuff having the above-described structure, the hard curved plate held between the inner and outer cloths sewn to each other, the locking fastener fixed to the outer surface of the outer cloth, and the inner cloth. Since it has an air bag fixedly installed on the inner peripheral side and an optical distance sensor installed opposite to the inside and outside of the air bag, the local displacement amount of the arterial wall can be directly measured by the optical distance sensor. It is possible to measure and determine the maximum and minimum blood pressure values based on this displacement amount.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. 1 and 2 show an embodiment of a cuff for a blood pressure monitor according to the present invention. Figure 3
Shows an example of a sphygmomanometer to which the cuff 10 of the present invention is applied. The blood pressure monitor shown in the figure includes a cuff 10, an optical distance sensor 12, and a digital data processing unit 14. The cuff 10 is a main part of the subject, specifically, the upper arm 1.
6, which is shown in detail in FIGS.

The cuff 10 shown in the figure is a hard curved plate 10a which is formed of a thin synthetic resin and curved in an arc shape so that it can be bent and deformed.
And an outer cloth 10b surrounding the outer circumference of the curved plate 10a.
And an inner cloth 10c sewn to the outer cloth 10b so as to surround the inner circumference of the curved plate 10a, an air bag 10d provided on the inner surface side of the inner cloth 10c, and an outer circumference of the outer cloth 10b. And a locking fastener 10e that locks the end of the inner cloth 10c.

The air bag 10d is composed of a bag body 10g made of a transparent synthetic resin sheet in which reinforcing fibers 10f are incorporated in a lattice shape and sealed. The reinforcing fiber 10 is added to the bag body 10g in order to prevent the bag body 10g from being stretched when being pressed or pulsating.
Incorporate f as a unit. When injecting air into the bag 10g through a pipe 18 described later to inflate it, the bag 10g can be inflated in proportion to the amount of air injected.

A pipe 18 for injecting air is communicatively connected to the inside of the bag 10g. A pressure sensor 20 and an electromagnetic control valve 22 are connected to the outer end of the pipe 18. A pump 24 that sends out air is connected to the electromagnetic control valve 22, and the electromagnetic control valve 22 and the pump 24 are controlled by a pump control unit 26.

The detection signal of the pressure sensor 20 is input to the digital data processing unit 14 via the bandpass filter 28 and the A / D converter 30. The pump control unit 26 includes
A control signal is sent from the digital data processing unit 14 based on the detection signal of the pressure sensor 20. The optical distance sensor 12 includes a photocoupler 12a fixed to the outer surface of the outer side of the bag 10g, and a reflection plate 1 fixed to the outer surface of the inner side of the bag 10g so as to face the photocoupler 12a.
2b and.

The photocoupler 12a is a combination of a light emitting diode and a phototransistor, and is set so that the light emitted from the light emitting diode is reflected by the reflector 12b and is incident on the phototransistor. The magnitude of the output of the phototransistor differs depending on the distance between the photocoupler 12a and the reflector 12b.
An output signal corresponding to the displacement of the artery is transmitted.

The light emitting diode of the photocoupler 12a is controlled to be turned on and off by a light emission control unit 32 connected to the digital data processing unit 14. The phototransistor of the photocoupler 12a includes a bandpass filter 34 and an A /
The digital data processing unit 14 is connected via the D converter 36, and the detection signal of the transistor is digitized and input to the processing unit 14.

In this embodiment, since the bag body 10g is made of a transparent synthetic resin sheet, the photo coupler 12a and the reflection plate 12b are arranged on the outer surface side thereof.
When the bag 10g is formed of an opaque synthetic resin sheet, the photocoupler 12a and the reflector 12b may be arranged on the inner surface side thereof. Further, in the blood pressure monitor cuff 10 of the present invention,
The optical distance sensor 12 includes a photocoupler 12a and a reflector 12.
Not only the combination of b, but also the combination of the light emitting diode and the phototransistor can be adopted, and in this case, they may be installed so as to face the inner and outer surfaces of the bag body 10g.

The digital data processing unit 14 is composed of a so-called microcomputer and includes a cpu and a memory. The digital data processing unit 14 has a display unit 38 for displaying the maximum and minimum blood pressure values.
Are connected through the interface. When measuring blood pressure, first, the cuff 10 is attached to the upper arm 16 of the subject. At this time, the reflector 1 is placed on the artery of the upper arm 16.
2b is set so that the cloths 10b and 10c are hooked on the locking fastener 10e and fixed.

In this case, in order to surely position the reflector 12b on the artery of the upper arm 16 of the subject, for example, as shown by phantom lines in FIG. By arranging it along with, the reflection plate 12b of one of the sensors 12 can be positioned on the artery. When using a plurality of sensors 12, each sensor 12
It is only necessary to compare the output values of the above and select the one that outputs the largest output signal.

When the wearing of the cuff 10 is completed, the preparation for blood pressure measurement is completed. Therefore, the digital data processing unit 14 sends an output signal to the electromagnetic control unit 22 to open the electromagnetic control valve 22. Then, the electromagnetic control valve 22 is controlled based on the detection signal of the pressure sensor 20, and the air bag 10d of the cuff 10 is controlled.
Constant speed pressurization control for increasing the internal pressure at a constant speed is performed.

At this time, in the cuff 10 of this embodiment, the reinforcing fibers 10f are incorporated in the bag body 10g of the air bag 10d in a lattice shape, and the inelastic curved plate 10 is provided on the outer peripheral side of the bag body 10d.
Since a is interposed, the expansion and contraction of the bag body 10d itself is restricted by the reinforcing fiber 10f, and the outward expansion of the bag body 10d is restricted by the curved plate 10a.
Is prevented.

Therefore, in the air bag 10d, only the inner side of the air bag 10g is displaced inwardly to compress the artery while the outer position of the bag body 10g is maintained. The detection signals sent from the optical distance sensor 12 are sequentially fetched by the data processing unit 14. Since the output signal of the optical distance sensor 12 includes a portion corresponding to the bulge of the air bag 10d that is being pressurized at a constant speed, the photoelectric volume pulse wave signal obtained by removing the portion corresponding to this constant pressure is removed. Is calculated by the data processing unit 14, and the maximum and minimum blood pressures are determined based on this signal.

FIG. 4 shows an example of the photoelectric volume pulse wave signal. An example of a method for determining the maximum and minimum blood pressures based on this photoelectric plethysmogram signal will be described. Now, for example, the photoelectric volume pulse wave signals P ₁ , P ₂ , P _{3 for} each beat are ...
If P _n is extracted in the state as shown in FIG. 4, in the determination of the diastolic blood pressure, is there a flat portion s in each photoelectric volume pulse wave signal P ₁ , P ₂ , P ₃ ... P _n ? Detect whether or not.

Here, when the pressure in the air bladder 10d is smaller than the minimum blood pressure of the subject in the process of pressurizing the pressure in the air bladder 10d at a constant speed, the photoelectric volume pulse wave signal is the air bladder 10d. Pulsates without being affected by the pressure of the photoplethysmogram (photoelectric volume pulse wave signals P _{1 to} P ₆ in FIG. 4). However, when the pressure in the air bladder 10d becomes higher than the minimum blood pressure of the subject, when the pressure in the artery is lower than the pressure in the air bladder 10d, the photoelectric plethysmography signal has a flat portion s where there is no pressure change. To do. Therefore, the photoelectric volume pulse wave signal P _{7 in} which the flat portion s is first generated is detected, and the minimum blood pressure is determined when this photoelectric volume pulse wave signal P ₇ is detected.

In the determination of the diastolic blood pressure, for example, the photoelectric volume pulse wave signal P ₆ immediately before the photoelectric volume pulse wave signal P ₇ in which the flat portion s first appears is extracted from the inside of the air bag 10d. The pressure is used as the minimum blood pressure value, or the average value of the pressure in the air bag 10d at the time when the photoelectric volume pulse wave signal P ₇ and the photoelectric volume pulse wave signal P ₆ are extracted is used as the minimum blood pressure value.

In the determination of the minimum blood pressure in this case, as shown in FIG. 4, when the pressure in the air bag 10d becomes higher than the minimum blood pressure of the subject, the photoelectric volume pulse wave signal corresponds to Korotkoff sound. Since the high-speed displacement section K is generated, it is possible to detect the photoelectric volume pulse wave signal first developed by the high-speed displacement section K and obtain the minimum blood pressure value by the same method as the flat section s. Further, it is also possible to detect both the flat portion s and the high-speed displacement portion K and similarly obtain the minimum blood pressure value.

On the other hand, in the determination of the systolic blood pressure, the time when the photoelectric plethysmogram signal disappears is determined to be the systolic blood pressure. That is, when the pressure in the air bladder 10d is pressurized at a constant rate, if the pressure becomes higher than the systolic blood pressure value, the pulsation of the artery is suppressed by the pressure, and the displacement of the optical distance sensor 12 does not occur. Then, the time when the photoelectric plethysmogram signal is no longer detected is determined as the subject's systolic blood pressure.

According to the sphygmomanometer cuff of the present embodiment constructed as described above, between the air bag 10d fixedly provided on the inner peripheral side of the inner cloth 10c and the inside and outside of the air bag 10d. Since it has the optical distance sensor 12 installed oppositely, it is possible to directly measure the local displacement amount of the arterial wall by the optical distance sensor 12 and obtain the maximum and minimum blood pressure values based on this displacement amount. It enables accurate blood pressure measurement.

[0031]

As described above in detail in the embodiments,
According to the sphygmomanometer cuff according to the present invention, the local displacement amount of the arterial wall is directly measured by the optical distance sensor, and the maximum and minimum blood pressure values are obtained based on this displacement amount. The blood pressure value can be obtained.

[Brief description of drawings]

FIG. 1 is a development view showing an embodiment of a sphygmomanometer cuff according to the present invention.

FIG. 2 is a cross-sectional view of a main part of the sphygmomanometer cuff according to the present invention.

FIG. 3 is a configuration block diagram of a sphygmomanometer to which the cuff according to the present invention is applied.

4 is a waveform diagram showing an example of a pulse wave detected by the cuff for a blood pressure monitor of FIG.

[Explanation of symbols]

10 cuffs 10a curved plate 10b outer cloth 10c inner cloth 10d air bag 10e Locking fastener 10f Reinforcing fiber 10g bag 12 Optical distance sensor 12a Photo coupler 12b reflector 14 Digital data processing unit

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Katsuyoshi Kanayama 1-243 Asahi, Kitamoto City, Saitama Prefecture, A & D Development and Technology Center, Inc. (72) Shigeru Ishizuka, Asahi Kitamoto City, Saitama Prefecture Chome No. 243 A & D Co., Ltd. Development and Technology Center (56) Reference JP-A-6-292659 (JP, A) JP-A-59-51837 (JP, A) JP-A-61-100228 ( JP, A) Actual Kaihei 3-73103 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) A61B 5/02-5/03

Claims (4)

(57) [Claims] 1. A cuff for a sphygmomanometer, which is attached to a main part of a subject and injects air to press an artery, a hard curved plate held between cloths sewn inside and outside, and the outside. And a locking fastener fixed to the outer surface of the cloth, an air bag fixedly provided on the inner peripheral side of the inner cloth, and an optical distance sensor installed to face the inside and outside of the air bag. Characteristic cuff for blood pressure monitor. 2. The optical distance sensor comprises a reflection plate provided inside the air bag and a light receiving and emitting element provided outside the air bag. The cuff for the blood pressure monitor described. 3. The optical distance sensor has a pair of light-receiving and light-emitting elements, one of the elements is provided inside the air bag, and the other of the elements is provided outside the air bag. The cuff for a sphygmomanometer according to claim 1, wherein. 4. The air bag according to claim 1, wherein the air bag comprises a transparent bag body and a lattice-shaped reinforcing fiber integrally incorporated in the bag body. Cuff for blood pressure monitor.