JP2000166887A - Carotid pulse wave detecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a carotid pulse wave detecting device which can press a carotid artery with optimum pressing force. SOLUTION: A circumferential wall 26 surrounding an opening of housing 20 presses a epidermis 16 on a carotid artery 28. Thereby, the position of the pressing face 34 of a pressing sensor 24 housed in the housing 20, corresponding to the opening face of the housing 20 is adjusted by a pressing chamber pressure adjusting device 50 in a state in which a carotid pulge wave detecting device 12 is mounted on collum of a subject. Accordingly, the pressing force of the pressing sensor 24 for pressing the carotid artery 28 can be adjusted to a previously predetermined optimum pressing force POPT.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carotid artery wave detecting device for detecting a pulse wave generated from a carotid artery.

[0002]

2. Description of the Related Art Detection of carotid artery waveforms for diagnostic purposes,
To detect the carotid artery wave as a reference point of the pulse wave propagation velocity, press the pressure sensor held by a predetermined spring-type holder or held by a wearing band with a predetermined pressing force against the carotid artery. Accordingly, various carotid artery wave detecting devices for detecting a pulse wave generated from the carotid artery have been proposed.

[0003]

However, in the conventional carotid artery wave detecting device, the pressing force of the predetermined spring-type holder or the mounting band is all concentrated on the pressing surface of the pressure sensor, and the strength of the spring or the mounting force is increased. The pressing force with which the pressure sensor presses the carotid artery is determined by the tightening strength of the band. Therefore, it has been difficult to press the carotid artery with an optimum pressing force.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a carotid artery wave detecting device capable of pressing a carotid artery with an optimum pressing force. is there.

[0005]

The gist of the present invention to achieve the above object is to provide a carotid artery wave detecting device for pressing a carotid artery of a living body and detecting a pulse wave from the carotid artery. (A-1) an opening in one direction, a peripheral wall surrounding the opening has a container-shaped housing for pressing the upper epidermis of the carotid artery, and (a-2) a pressing surface for pressing the carotid artery. A pressure sensor that is housed in the housing and outputs a carotid artery signal representing the pulse wave of the carotid artery, and a carotid artery wave sensor attached to the neck of the living body; A pressure adjusting device that adjusts the pressure at which the pressure sensor presses the carotid artery to a preset optimal pressing force by adjusting the position of the pressing surface of the sensor with respect to the opening surface of the housing. It is in.

[0006]

In this manner, the peripheral wall surrounding the opening of the housing presses the epidermis above the carotid artery, so that the carotid artery wave sensor is mounted on the neck of the living body.
Since the position of the pressing surface of the pressure sensor housed in the housing with respect to the opening surface of the housing can be adjusted by the pressing force adjusting device, the pressing force by which the pressure sensor presses the carotid artery is set to a preset optimal pressing force. Can be adjusted.

[0007]

In another preferred embodiment of the present invention, preferably, the carotid artery wave detecting device is provided in the housing, and accommodates the pressure sensor in a state where a pressing surface of the pressure sensor is protruded. Further comprising a sensor cover forming a sealed pressure chamber on the base end side of the pressure sensor, wherein the pressing force adjusting device adjusts the pressure of the pressure chamber to the optimum pressing force to thereby adjust the pressure surface of the pressure sensor. The position of the housing with respect to the opening surface is adjusted. With this configuration, the pressure of the pressure chamber formed on the base end side of the pressure sensor by the sensor cover housing the pressure sensor is adjusted to the optimum pressing force by the pressing force adjusting device,
The position of the pressing surface of the pressure sensor with respect to the opening surface of the housing is adjusted, and the pressure sensor can press the carotid artery with the optimum pressing force.

[0008] Preferably, the carotid artery wave detecting device includes a preset pressure sufficiently including the optimal pressing force by the pressure sensor by the pressing force adjusting device for pressing the carotid artery. Pressing force changing means for sequentially changing in a changing range, and a fluctuation component calculating means for calculating a periodically fluctuating fluctuation component of the carotid artery wave signal output from the pressure sensor in a process of changing the pressing force by the pressing force changing means. And an optimum pressing force determining means for determining the pressing force when the fluctuation component calculated by the fluctuation component calculating means is maximum as the optimum pressing force. According to this configuration, the pressing force changing unit changes the pressing force for pressing the carotid artery by the pressure sensor of the pressing force adjusting device sequentially in a preset pressure change range that sufficiently includes the optimal pressing force, and The component calculating means calculates a periodically fluctuating component of the carotid artery signal output from the pressure sensor in the process of changing the pressing force, and the optimal pressing force determining means calculates the fluctuating component. Since the pressing force when the fluctuation component is the maximum is determined as the optimum pressing force, even if the test subject is different or the optimum pressing force is different due to a different measurement position, the pressure sensor can detect the carotid artery. Pressing can be performed with the optimum pressing force.

[0009]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a diagram showing a configuration of a carotid artery wave detection device 10 which is an example of the present invention.

In FIG. 1, a carotid artery wave sensor 12 is mounted on a skin 16 of a cervix 14 of a living body by a mounting belt 18. As shown in the sectional view of the carotid artery wave sensor 12 in FIG.
And a sensor cover 22 provided on the housing 20.
And the pressure sensor 24 housed in the sensor cover 22
It is comprised including.

The housing 20 is made of, for example, a relatively hard resin or rubber, and has a circular bottom 2.
5 and a cylindrical peripheral wall 26 whose diameter becomes shorter toward the bottom 25 side. A container having an opening surface that opens in a plane by closing one surface of the peripheral wall 26 with the bottom 25 is formed. Has formed. Then, the peripheral wall 26 presses the epidermis 16 above the carotid artery 28.

The sensor cover 22 has a cylindrical shape that opens in one direction, and is fixed substantially at the center of the bottom 25 of the housing 20 so that the opening direction matches the opening direction of the housing 20. A projecting ring 30 is provided at the open end of the sensor cover 22 to protrude in a direction to narrow the opening surface in order to prevent the pressure sensor 24 from dropping off.

The pressure sensor 24 includes a cylindrical body 32 accommodated in the sensor cover 22, a pressing member 36 having a pressing surface 34 pressed toward the upper skin 16 of the carotid artery 28,
It comprises a pressure detecting element 38 for detecting a carotid artery wave by the pressure from the pressing member 36, and a conducting wire 40 connected to the pressure detecting element 38.

The pressure sensor 24 is slidably accommodated in the sensor cover 22 by making the cylindrical body 32 have the same size as the inside of the protruding ring 30. The bottom plate 42 provided at the bottom of the cylindrical body 32 has the same shape as the inner peripheral surface of the sensor cover 22 to form a sealed pressure chamber 44 inside the sensor cover 22. The engagement of the protrusion 42 with the protruding ring 30 of the sensor cover 22 prevents the pressure sensor 24 from dropping off the sensor cover 22.

The pipe 46 is connected to the bottom of the sensor cover 22 and the housing 2 so that the tip is located in the pressure chamber 44.
0 through the bottom 25. This piping 46
By adjusting the pressure P in the pressure chamber 44 through the opening, the position of the pressing surface 34 of the pressure sensor 24 with respect to the opening surface of the housing 20 is adjusted, and the pressing surface 34 of the pressure sensor 24 The carotid artery 28 is pressed with a pressing force corresponding to P. Then, the pressure sensor 24 detects the carotid artery 2
8, the pulsation of the carotid artery 28 is
Through a lead wire 46 connected to the pressure detecting element 38 and a cord 48 connected to the lead wire 46,
A carotid artery signal SM representing the carotid artery is output.

Returning to FIG. 1, the pressure chamber pressure adjusting device 50
A pressure adjusting valve 52 and an air pump 54 adjust the pressure P in the pressure chamber 44 to a preset optimal pressing force P _OPT , so that the pressing surface 34 of the pressure sensor 24 is adjusted.
Of the housing 20 with respect to the opening surface of the housing 20.
That is, the pressure regulating valve 52 regulates the pressure of air from the air pump 54, and adjusts the pressure of the pressure chamber 4 formed in the sensor cover 22.
Optimum pressing force the pressure P is preset in the 4 pressure regulated to P _OPT. When the pressure P in the pressure chamber 44 is adjusted to the optimum pressing force P _OPT , the pressure sensor 24 moves the carotid artery 28 to the optimum pressing force P _OPT.
Press with _OPT . Therefore, the pressure chamber pressure adjusting device 50 functions as a pressing force adjusting device.

The carotid artery wave signal SM output from the carotid artery wave sensor 12 is amplified by the amplifier 56, A / D converted by the A / D converter 58, and supplied to the arithmetic and control unit 60. The arithmetic and control unit 60 includes a CPU 62, a ROM 6
4, a so-called microcomputer having a RAM 66, an I / O port (not shown), and the like.
The PU 62 outputs a drive signal from an I / O port by executing signal processing using a storage function of the RAM 66 in accordance with a program stored in the ROM 64 in advance, and outputs a drive signal from the I / O port to the pressure regulating valve 52 and the air By controlling the pump 54, the pressure in the pressure chamber 44 is changed within a predetermined pressure change range sufficiently including the optimum pressing force _POPT , and the carotid artery output from the pressure sensor 24 in the process of changing the pressure. The optimum pressing force _POPT is determined based on the wave signal SM. Further, after the optimum pressing force is determined, the pressure P in the pressure chamber 44 becomes the optimum pressing force _POPT .
The pressure control valve 52 and the air pump 54 are controlled, and a carotid artery wave represented by the carotid artery wave signal SM is displayed on a display (not shown) based on the carotid artery wave signal SM output from the pressure sensor 24 in that state, or , A reference point to be used as a reference point of the pulse wave propagation velocity is detected.

FIG. 3 illustrates a main part of an optimum pressing force determining function for determining the optimum pressing force _POPT among the control functions of the arithmetic and control unit 60 in the carotid artery wave detecting device 10 configured as described above. FIG. 3 is a functional block diagram illustrating the operation of the embodiment. In the figure, the pressing force changing means 70 is set in advance to include the pressing force by which the pressure sensor 24 presses the carotid artery 28 by the pressure chamber pressure adjusting device 50 (that is, the pressing force adjusting device) sufficiently including the optimum pressing force _POPT. In the range of pressure change. That is, a drive signal is output to the pressure regulating valve 52 to sequentially change the pressure P in the pressure chamber 44 within a preset pressure change range sufficiently including the optimum pressing force _POPT .

The fluctuation component calculating means 72 detects the pressure sensor 2 during the process of changing the pressing force by the pressing force changing means 70.
A fluctuation component that periodically fluctuates in the carotid artery signal SM output from 4 is calculated. As shown in FIG. 4, the carotid artery wave pulsates every beat, and has a fluctuation component AC and a fixed component DC. Therefore, the fluctuation component calculating means 72 detects, for example, each pulse and the pulse wave peak point a and the pulse wave rising point b, and determines the signal strength at the pulse wave peak point a and the signal strength at the rising point b. And the variation component AC
Is calculated as

The optimum pressing force determining means 74 determines the pressing force when the fluctuation component AC calculated by the fluctuation component calculating means 72 becomes the maximum as the optimum pressing force _POPT . That is, the pressure in the pressure chamber 44 when the fluctuation component AC calculated by the fluctuation component calculation means 72 becomes the maximum is determined as the optimum pressing force _POPT . If the pressing force of the pressure sensor 24 is too small, the carotid wave signal SM output from the pressure sensor 24 will be small. On the other hand, if the pressing force of the pressure sensor 24 is too large, the fixed component D of the carotid artery wave signal SM
Although C increases, the pulsation decreases due to excessive compression of the carotid artery 28, so that the fluctuation component AC decreases. Therefore,
The optimum pressing force determining means 74 determines the pressure P in the pressure chamber 44 when the fluctuation component AC is maximized as the optimum pressing force _POPT .

FIG. 5 is a flowchart for explaining the main part of the operation of the arithmetic and control unit 60 for determining the optimum pressing force.

In step S1 of FIG. 5 (hereinafter, the steps are omitted), a drive signal is output to the pressure regulating valve 52 and the air pump 54, and the pressure P in the pressure chamber 44 is set to a preset pressure set value P _SET. Up to The initial value of the pressure set value P _SET is the lower limit value P of the pressure change range.
_L is set. At S2, the pressure P in the pressure chamber 44 is set to the pressure set value P _SET, and the pressure sensor 24 presses the carotid artery 28 with the pressure set value P _SET , and is preset to several seconds to several tens of seconds. The carotid wave signal SM output from the pressure sensor 24 is read for
It is stored in a pulse wave storage area (not shown) of the AM 66.

At S3, a constant value α is added to the pressure set value P _SET . This constant value alpha, is preset as a value sufficiently smaller than the difference between the upper limit value P _L and the lower limit value P _L of the pressure variation range. In the following S4, the pressure set value P _SET
There whether it is greater than the upper limit value P _U of the pressure variation range is determined. Initially, the determination in S4 is denied, and the pressure P in the pressure chamber 44 is increased to the pressure set value P _SET determined in S3 by repeatedly executing S1 and subsequent steps. 24 is a pressure chamber 4
The carotid artery wave signal S output from the pressure sensor 24 in a state where the carotid artery 28 is pressed with the pressing force corresponding to the pressure P in
M is read. Therefore, S1 to S4 correspond to the pressing force changing means 70.

However, if the pressure set value P _SET exceeds the upper limit value P _U of the pressure change range, the judgment in S4 is denied, and in S5 corresponding to the fluctuation component calculation means 72, S5
2 based on the carotid artery wave signal SM stored in a pulse wave storage area (not shown) of the RAM 66.
Is calculated for each beat, and in subsequent S6, S
The average value of the fluctuation component AC calculated for each beat in step 5 is calculated for each pressure set value P _SET .

In S7 corresponding to the optimum pressing force determining means 74, the pressure set value P _{SET at} which the average value of the fluctuation component AC calculated in S6 indicates the largest value is determined as the optimum pressing force P _OPT . Then, in S8, a drive signal is output to the pressure regulating valve 52, and the pressure P in the pressure chamber 44 is increased in S7.
In the control of the determined optimum pressing force P _OPT, the pressure sensor 24 presses the carotid artery 28 at the optimum pressing force P _OPT.

As described above, according to the present embodiment, the peripheral wall 26 surrounding the opening of the housing 20 presses the epidermis 16 above the carotid artery 28, so that the carotid artery wave sensor 12 attaches to the neck 14 of the living body. In the mounted state, the pressure sensor 2 housed in the housing 20 is controlled by the pressure chamber pressure adjusting device 50.
4, the position of the pressing surface 34 with respect to the opening surface of the housing 20 can be adjusted, so that the pressing force by which the pressure sensor 24 presses the carotid artery 28 is set to a preset optimum pressing force P.
Can be adjusted to _OPT .

According to this embodiment, the sensor cover 2
2 accommodates the pressure sensor 24 so that the pressure sensor 2
4 of the pressure of the proximal pressure chamber formed side 44, by adjusting the optimum pressing force P _OPT the pressure chamber pressure regulator 50, the pressing surface 34 of the pressure sensor 24, the position with respect to the opening surface of the housing 20 Is adjusted, and the pressure sensor 24 can press the carotid artery 28 with the optimum pressing force _POPT .

Further, according to the present embodiment, the pressing force for pressing the carotid artery 28 by the pressure sensor 24 of the pressure chamber pressure adjusting device 50 is determined by the pressing force changing means 70 (S1 to S4) to be the optimum pressing force _POPT . It is sequentially changed within a predetermined pressure change range that sufficiently includes the fluctuation component calculation means 72 (S5).
In the process of changing the pressing force, the pressure sensor 24
The periodically fluctuating component AC of the carotid artery wave signal SM output from is calculated, and the optimal pressing force determining means 74 (S
In 7), the pressing force when the fluctuation component AC calculated by the fluctuation component calculating means 72 (S5) is maximum is determined as the optimum pressing force P _OPT , so that the subject is different or the measurement position is different. Optimal pressing force P due to different
_{Even if the OPT} is different, the pressure sensor 24 can press the carotid artery 28 with the optimum pressing force _POPT .

Although the embodiment of the present invention has been described with reference to the drawings, the present invention can be applied to other embodiments.

For example, in the above-described embodiment, the optimum pressing force P _OPT is determined by the optimum pressing force determining means 74 (S7) as the optimum pressing force P _OPT when the fluctuation component AC is maximized. _OPT may be set to a constant value in advance.

In the above-described embodiment, the pressure chamber pressure adjusting device 50 (that is, the pressure regulating valve 52 and the air pump 54) functions as a pressing force adjusting device, and the sensor cover 22 is formed by housing the pressure sensor 24. Pressure chamber 4
By adjusting the pressure P in the pressure sensor 24, the pressure sensor 24
The position of the pressing surface 34 with respect to the opening surface of the housing 20 has been adjusted.
4 is provided with a rack in the pressing direction, and a pinion that meshes with the rack is fixed to the housing 20, so that the position of the pressing surface 34 of the pressure sensor 24 with respect to the opening surface of the housing 20 is adjusted. , And other formats.

In the above-described embodiment, the peripheral wall 26 is cylindrical, that is, the cross section is circular. However, the peripheral wall 26 may have another shape such as a square such as a square or a pentagon, or an ellipse. Good.

In the above-described embodiment, the housing 16
Is open so that its opening surface is flat, but it may be opened so that its opening surface has a predetermined curvature along the neck of a living body.

In the above-described embodiment, the carotid artery wave sensor 12 is mounted on the neck 14 of the living body by the mounting belt 18, but the internal pressure of the housing 20 is made negative, and the suction force by the negative pressure is used. A type that is attached to the neck 14 of the living body, or a gripping device that curves along the neck 14 of the living body, has the carotid artery wave sensor 12 fixed to one end, and holds the neck 14 Accordingly, the carotid artery wave sensor 12 may be attached to the neck 14 of the living body in another form, such as a form in which the carotid artery wave sensor 12 is attached to the neck 14 of the living body.

The present invention can be variously modified without departing from the gist thereof.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration of a carotid artery wave detection device according to an embodiment of the present invention.

FIG. 2 is a sectional view of the carotid artery wave sensor of the embodiment of FIG.

3 is a functional block diagram illustrating a main part of an optimum pressing force determining function for determining an optimum pressing force among control functions of the arithmetic and control unit in the carotid artery wave detecting device in FIG. 1;

FIG. 4 is a diagram illustrating an example of a carotid artery wave.

5 is a flowchart illustrating an optimum pressing force determination routine for determining an optimum pressing force among the control operations of the arithmetic and control unit in the carotid artery wave detection device of FIG. 1;

[Description of sign]

 10: Carotid artery wave detection device 12: Carotid artery wave sensor 20: Housing 22: Sensor cover 24: Pressure sensor 26: Peripheral wall 50: Pressure chamber pressure adjusting device (pressing force adjusting device) 70: Pressing force changing means 72: Variable component Calculating means 74: Optimal pressing force determining means

Claims (2)

[Claims] 1. A carotid artery wave detection device for detecting a pulse wave from a carotid artery by pressing the carotid artery of a living body, wherein the carotid artery wave detection device is opened in one direction, and a peripheral wall surrounding the opening is located above the carotid artery. A container-shaped housing that presses the epidermis, a pressure sensor that includes a pressing surface that presses the carotid artery, is housed in the housing, and outputs a carotid artery wave signal representing a pulse wave of the carotid artery, A carotid artery wave sensor attached to the neck of the living body, and adjusting a position of a pressing surface of the pressure sensor with respect to an opening surface of the housing, so that a pressing force by which the pressure sensor presses the carotid artery is determined in advance. A pressure adjusting device that adjusts the pressure to a set optimal pressing force. 2. A sensor cover provided in the housing and accommodating the pressure sensor in a state where a pressing surface of the pressure sensor protrudes, and forming a sealed pressure chamber at a base end side of the pressure sensor. 2. The pressure adjusting device according to claim 1, wherein the pressing force adjusting device adjusts the pressure of the pressure chamber to the optimum pressing force, thereby adjusting the position of the pressing surface of the pressure sensor with respect to the opening surface of the housing. Carotid wave detection device.