JP2010115321A - Pulse wave propagation information measuring apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pulse wave propagation information measuring apparatus capable of relatively evaluating pulse wave propagation information for each kind of the artery. <P>SOLUTION: The pulse wave propagation information measuring apparatus 20 measures pulse wave propagation information related to the speed of propagating pulse waves inside the artery of a subject 10 on the basis of the pulse waves detected from a prescribed part of the subject 10. Since the pulse wave propagation information measured corresponding to each of two or more kinds of the artery in the subject 10 is relatively displayed within the same screen, the pulse wave propagation information for each kind of the artery is objectively and visually recognizably indicated. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an improvement in a pulse wave propagation information measuring apparatus that measures information related to a speed at which a pulse wave propagates through an artery of a living body, such as a pulse wave propagation speed and a pulse wave propagation time.

  2. Description of the Related Art There is known a pulse wave propagation information measuring device that measures pulse wave propagation information related to a speed at which a pulse wave propagates through an artery of the living body based on a pulse wave detected from a predetermined site in the living body. As one aspect thereof, a technique for evaluating the degree of arteriosclerosis based on the pulse wave velocity information by utilizing the influence of the degree of arteriosclerosis of the living body on the pulse wave velocity information is known. In the measurement of the pulse wave velocity, for example, pulse waves are detected at two points in the living body to be measured, and the pulse wave velocity is measured from the distance between the two points and the time difference between the pulse wave propagation. This pulse wave velocity is a value that depends on the diameter and elasticity of the blood vessel (artery), and it is known that the velocity increases as the hardness of the blood vessel to be processed increases. Utilizing such properties, for example, in the arteriosclerosis degree evaluation apparatus described in Patent Document 1, the arteriosclerosis degree or blood vessel age of the target living body from the pulse wave velocity measured as described above Is evaluated.

JP 2004-321438 A

  By the way, arteries in a living body can be classified into a plurality of types based on their characteristics, for example, elastic arteries, muscular arteries, and arteries having intermediate properties. Regarding this classification, the aorta belongs to an elastic artery, the peripheral artery belongs to a muscular artery, and the middle artery belongs to an artery having intermediate properties. In addition, it is known that the pulse wave propagation speeds of the different types of arteries are different. Similarly, regarding the degree of progression of arteriosclerosis, it is considered that there is a time difference depending on the type of artery even in the same living body. For example, it is known that arteriosclerosis of the aorta begins in the late 10s, and the progress of pulse wave velocity tends to be saturated in the 60s. Therefore, the average pulse wave velocity including the aorta and peripheral artery measured by the conventional technique as described above mainly reflects the change in the pulse wave velocity of the aortic component until the 60s, and thereafter. Is considered to depend on changes in the pulse wave velocity related to other types of arteries, such as peripheral arterial components. However, the present situation is that a pulse wave propagation information measuring apparatus capable of relatively evaluating the pulse wave propagation information for each type of artery has not been developed yet.

  The present invention has been made in the background of the above circumstances, and its object is to provide a pulse wave propagation information measuring device capable of relatively evaluating pulse wave propagation information for each type of artery. It is in.

  In order to achieve such an object, the gist of the present invention is that a pulse wave related to a speed at which a pulse wave propagates through an artery of the living body based on a pulse wave detected from a predetermined site in the living body. A pulse wave propagation information measuring apparatus for measuring propagation information, characterized by relatively displaying pulse wave propagation information measured corresponding to each of a plurality of types of arteries in the living body on the same screen. It is.

  In this way, the pulse wave propagation information measuring device that measures the pulse wave propagation information related to the speed at which the pulse wave propagates through the artery of the living body based on the pulse wave detected from a predetermined site in the living body. Since the pulse wave propagation information measured corresponding to each of a plurality of types of arteries in the living body is relatively displayed in the same screen, the pulse wave propagation information for each type of artery is objective. Can be shown visually. That is, it is possible to provide a pulse wave propagation information measuring device that can relatively evaluate pulse wave propagation information for each type of artery.

  Here, preferably, pulse wave propagation information measured corresponding to each of the aorta and the peripheral artery in the living body is relatively displayed on the same screen. In this way, the pulse wave propagation information corresponding to each of the aorta and the peripheral artery can be objectively shown.

  Preferably, the pulse wave propagation information corresponding to the aorta corresponds to the speed at which the pulse wave propagates through the section from the artery origin to the thigh in the living body. In this way, pulse wave propagation information corresponding to the aorta can be obtained in a practical manner.

  Preferably, the pulse wave propagation information corresponding to the aorta corresponds to a speed at which the pulse wave propagates through a section from the arterial origin to the upper arm in the living body. In this way, pulse wave propagation information corresponding to the aorta can be obtained in a practical manner.

  Preferably, the pulse wave propagation information corresponding to the peripheral artery corresponds to a speed at which the pulse wave propagates through a section from the thigh to the ankle in the living body. In this way, pulse wave propagation information corresponding to the peripheral artery can be obtained in a practical manner.

  Preferably, pulse wave propagation information measured corresponding to each of the aorta, peripheral artery, and peripheral arteriole in the living body is relatively displayed on the same screen. In this way, the pulse wave propagation information corresponding to the aorta, the peripheral artery, and the peripheral arteriole can be objectively shown.

  Preferably, the pulse wave propagation information corresponding to the peripheral arteriole corresponds to the speed at which the pulse wave propagates through the section from the ankle part to the toe part in the living body. In this way, pulse wave propagation information corresponding to peripheral arterioles can be obtained in a practical manner.

  Preferably, the pulse wave propagation information measured corresponding to the arteries in the left and right bodies with the median plane of the living body as a symmetry plane is relatively displayed on the same screen. In this way, the pulse wave propagation information for each type of artery in each of the left and right bodies can be objectively shown.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration of a pulse wave propagation information measuring device 20 according to an embodiment of the present invention. As shown in FIG. 1, the pulse wave propagation information measuring device 20 of this embodiment includes a neck 11 as a pulse wave and blood pressure value measurement site for calculating a pulse wave velocity related value (pulse wave propagation information), Upper arm 12 (upper right arm 12R and left upper arm 12L), thigh 14 (right thigh 14R and left thigh 14L), ankle 16 (right ankle 16R and left ankle 16L), and ankle 18 (the right footpad 18R and the left footpad 18L) are selected, and in the pulse wave propagation information measuring device 20, the upper arm 12, the thigh 14, and the ankle 16 which are measurement sites are selected. , And the toe 18 have the same height, and the measurement described in detail below is performed in a state where the subject 10 to be measured is in the prone position, the lateral position, or the supine position. Done. In addition, although the pulse wave propagation information measuring device 20 of the present embodiment is configured to calculate the blood pressure value together with the pulse wave propagation information, the blood pressure value need not necessarily be executable.

  The neck 11 is a part corresponding to a so-called neck, which connects the head and trunk of the subject 10 to be measured. The upper arm 12 is a portion corresponding to a so-called second arm, a portion between the shoulder joint and elbow joint of the subject 10 to be measured. The thigh 14 is a portion between the waist and the knee of the subject 10, that is, a portion having a thigh bone, and is a portion corresponding to a so-called thigh. The ankle portion 16 is a part on the heel of the subject's 10 leg (leg). The footpad 18 is a peripheral portion of the subject 10's foot, and is preferably its thumb.

  The pulse wave propagation information measuring device 20 includes upper arm cuffs 22R and 22L (hereinafter simply referred to as upper arm cuffs 22 unless otherwise specified) to be wound around the left and right upper arm portions 12R and 12L, respectively. ), Thigh cuffs 24R and 24L (hereinafter simply referred to as thigh cuffs 24 unless otherwise specified) to be wound around the left and right thighs 14R and 14L, and the left and right ankles, respectively. The ankle cuffs 16R and 16L to be wound around the portions 16R and 16L (hereinafter simply referred to as the ankle cuff 16 unless otherwise specified) and the left and right toe portions 18R and 18L, respectively. The toe cuffs 28R and 28L (hereinafter simply referred to as the toe cuff 28 unless otherwise specified) are provided. These upper arm cuff 22, thigh cuff 24, ankle cuff 26, and toe cuff 28 (hereinafter referred to as cuff 22, etc. unless otherwise specified) are wound portions. The compression band is a compression band, preferably having a rubber bag in a belt-shaped outer bag made of a non-extensible material such as cloth or polyester resin. Further, the upper arm cuff 22, the thigh cuff 24, the ankle cuff 26, and the toe cuff 28 are respectively connected to the corresponding pulse wave detectors 32UL, 32UR, 32TL, 32TR via the pipe 30. 32AL, 32AR, 32BL, and 32BR (hereinafter, simply referred to as pulse wave detection unit 32 unless otherwise distinguished). Since these pulse wave detectors 32 preferably have the same configuration, the pulse wave detector 32UL corresponding to the left upper arm 12L as shown in FIG. Detailed description.

  As shown in FIG. 1, the pulse wave detector 32 includes a pressure regulating valve 34, a pressure sensor 36, a static pressure discriminating circuit 38, and a pulse wave discriminating circuit 40, and the pipe 30 includes the pressure regulating valve 34 and the pressure sensor. 36. The pressure regulating valve 34 is connected to an air pump 44 via a pipe 42. The pressure regulating valve 34 is a pressure supply state that allows the pressure air generated by the air pump 44 to be supplied into the cuff 22 or the like, a pressure maintenance state that maintains the pressure in the cuff 22 or the like, an electric valve The four states of a slow exhaust pressure state in which the pressure in the cuff 22 and the like is gradually exhausted at a predetermined speed and a rapid exhaust pressure state in which the cuff 22 and the like are rapidly exhausted by controlling the opening degree Can be switched to.

The pressure sensor 36, and supplies a pressure signal SP _b representing the pressure by detecting the pressure of the cuff 22 Hitoshinai to the electrostatic pressure filter circuit 38 and a pulse-wave filter circuit 40. The static pressure discriminating circuit 38 includes a low-pass filter, discriminates the cuff pressure signal SK _b representing the steady pressure, that is, the cuff pressure PC _b included in the pressure signal SP _b, and displays the cuff pressure signal SK _b as A / A (not shown). The data is supplied to the arithmetic and control unit 46 through the D converter. The pulse wave discriminating circuit 40 includes a band-pass filter, and discriminates the pulse wave signal SM _b that is a vibration component of the pressure signal SP _b in terms of frequency and passes the pulse wave signal SM _b through an A / D converter (not shown). To the arithmetic control unit 46.

  Further, the pulse wave propagation information measuring device 20 includes a heart sound microphone 48. The heart sound microphone 48 is attached to a predetermined part on the chest epidermis corresponding to the arterial origin 19 of the subject 10, and detects and outputs a heart sound signal SH representing the heart sound. The heart sound signal SH output from the heart sound microphone 48 is supplied to the arithmetic control device 46 via the A / D converter 50. Since the heart sound represented by the heart sound signal SH is a heart beat synchronization signal generated in synchronization with the heart beat of the subject 10, the heart sound microphone 48 that outputs the heart sound signal SH functions as a heart beat synchronization signal detection device.

  The arithmetic control unit 46 is constituted by a so-called microcomputer having a CPU 52, a ROM 54, a RAM 56, an I / O port (not shown), and the like. The CPU 52 outputs a drive signal from the I / O port to execute the signal processing while using the temporary storage function of the RAM 56 in accordance with a program stored in the ROM 54 in advance, and thereby the air pump 44 and the pulse wave detection unit. While controlling the pressure regulation valve 34 in 32, various control, such as the pulse wave velocity calculation control mentioned later and pulse wave information display control, are performed. Further, the pulse wave propagation information measuring device 20 stores a display 58 that displays a predetermined video (image) according to the output from the arithmetic control device 46, and various types of information related to the control by the arithmetic control device 46. And a storage device 60 (see FIG. 2).

  The pulse wave propagation information measuring device 20 includes a pressure pulse wave detecting device 62 for detecting a pulse wave of the neck (carotid artery) 11 in the subject 10. FIG. 2 is a diagram illustrating the configuration of such a pressure pulse wave detection device 62. As shown in FIG. 2, the pressure pulse wave detecting device 62 is pressed against the carotid artery of the subject 10 and non-invasively detects the pressure pulse wave in the carotid artery. 64 and is attached to the neck 11 of the subject 10 by means of an attachment band 66 (see FIG. 1). As shown in detail in FIG. 2, the pressure pulse wave detection probe 64 is screwed into the sensor housing 68 having a container shape and the sensor housing 68 for moving the sensor housing 68 in the width direction of the carotid artery 11a. And a screw shaft 70 that is rotationally driven by a motor (not shown) provided in the case. The pressure pulse wave detection probe 64 is attached by the mounting band 66 so that the open end of the sensor housing 68 faces the body surface 11 b of the neck 11 of the living body.

  A pressure pulse wave sensor 74 is provided inside the sensor housing 68 through a diaphragm 72 so as to be capable of relative movement and project from the open end of the sensor housing 68. Pressure is applied by the sensor housing 68, the diaphragm 72, and the like. A chamber 76 is formed. Pressure air is supplied into the pressure chamber 76 from the air pump 78 via the pressure regulating valve 80, and the pressure pulse wave sensor 74 is thereby pressed with a pressure according to the pressure in the pressure chamber 76. It is pressed against the body surface 11b. The air pump 78 may be the same as the air pump 44 for supplying air pressure to the pulse wave detector 32 shown in FIG. The sensor housing 68 and the diaphragm 72 constitute a pressing device that presses the pressure pulse wave sensor 74 toward the carotid artery 11a. The screw pulse 70 and a motor (not shown) are pressed by the pressure pulse wave sensor 74. The pressing position changing device is configured to move the pressed position in the width direction of the carotid artery 11b.

  When the pressure pulse wave detection probe 64 configured as described above is pressed onto the carotid artery 11a on the body surface 11b in the neck 11 of the subject 10, the pressure pulse wave sensor 74 is connected to the carotid artery 11a. The pressure oscillation wave, that is, the pressure pulse wave generated from the pressure and transmitted to the body surface 11 b is detected, and the pressure pulse wave signal SMO representing the pressure pulse wave is supplied to the multiplexer 82. In accordance with the switching signal SC from the arithmetic and control unit 46, the multiplexer 82 sequentially applies the pressure pulse wave signal SMO output from the pressure sensing element (not shown) provided in the pressure pulse wave sensor 74 for each predetermined time band. This is supplied to the pass filter 84 and the low pass filter 86. The band-pass filter 84 includes an analog signal processing circuit having a capacitor and a coil or a resistor (not shown), and a frequency band (for example, 200 to 600 Hz) set as a frequency band of blood flow noise from the pressure pulse wave signal SMO. ) Signal (that is, blood flow noise component) is discriminated and the signal SM1 of the blood flow noise component is supplied to the arithmetic and control unit 46 via the A / D converter 88. Similarly to the band-pass filter 84, the low-pass filter 86 is composed of an analog signal processing circuit having a capacitor and a coil or a resistor (not shown), and a signal (representing a carotid artery wave included in the pressure pulse wave signal SMO ( SM2 (hereinafter referred to as a carotid wave signal) is extracted (discriminated), and the carotid wave signal SM2 is supplied to the arithmetic and control unit 46 via the A / D converter 90 as a pulse wave signal SN corresponding to the carotid artery 11a. To do. The arithmetic and control unit 46 outputs a drive signal to the air pump 78 and the pressure regulating valve 80 via a drive circuit (not shown) to adjust the pressure in the pressure chamber 76, and sends the multiplexer 82 to the multiplexer 82 based on the pulse period. The switching signal SC is output in a cycle set in advance in a sufficiently short cycle.

FIG. 3 is a functional block diagram for explaining a main part of the control function provided in the arithmetic and control unit 46. In FIG. 2, the upper arm cuff 22 (upper left) of the configurations corresponding to the upper arm cuff 22, the thigh cuff 24, the ankle cuff 26, and the toe cuff 28, respectively. Only the configuration corresponding to the arm cuff 22L) is illustrated. The cuff pressure control means 92 shown in FIG. 2 controls the cuff pressure by controlling the air pump 44 and the pressure regulating valve 34 corresponding to each pulse wave detector 32 connected to the air pump 44 in blood pressure measurement. The cuff pressure at 22 etc. is rapidly increased to a predetermined target pressure value P _CM (for example, a pressure value of about 180 mmHg for the upper arm cuff 22 and about 240 mmHg for the ankle cuff 26), and then 5 mmHg / sec. Decrease the pressure gradually. Further, in detecting the pulse wave, the cuff pressure in each of the cuffs 22 and the like is predetermined by controlling the air pump 44 and the pressure regulating valve 34 corresponding to each pulse wave detection unit 32 connected to the air pump 44. After the pressure is increased to the pulse wave detection pressure, the pressure is maintained for a certain time. The pulse wave detection pressure is lower than a general minimum blood pressure value, and the pressure vibration wave generated in the artery under the cuff due to the compression of the cuff 22 or the like is transmitted, and the pressure vibration wave is transmitted to the cuff 22 or the like. The pressure is such that the represented pulse wave is generated with a sufficient signal intensity, for example, 60 mmHg.

  The blood pressure value determining means 94 is based on a change in the amplitude of the pulse wave signal SM1 sequentially collected in the process in which the cuff 22 or the like wound around the measurement site is gradually lowered by the cuff pressure control means 92. Using a well-known oscillometric method, the maximum blood pressure value and the minimum blood pressure value, which are the blood pressure values BP of the measurement site corresponding to each cuff, are determined. The blood pressure value determined by the blood pressure value determining means 94 is stored in, for example, the storage device 60 and displayed on the display 58 according to a predetermined operation.

  The pulse wave velocity calculating means 96 is detected by the pulse wave detected from the measurement site around which the cuff 22 and the like are wound, the heart sound signal SH detected by the heart sound microphone 48, and the pressure pulse wave detector 62. On the basis of the carotid artery wave SN or the like, the pulse wave propagation speed is calculated as pulse wave propagation information related to the speed at which the pulse wave propagates through the artery of the subject 10. Specifically, a pulse is formed between the origin of the artery, that is, the heart, and a site where each measurement site, for example, the cuff 22 or the like is mounted or a site where the pressure pulse wave detection device 62 (a mounting band 66) is mounted. Calculate the speed of wave propagation. Here, as the pulse wave propagation information related to the speed of propagation of the pulse wave in the artery of the living body, the pulse wave propagation time that is the time during which the pulse wave propagates through the target artery or the pulse wave propagates through the artery. A pulse wave propagation speed, which is a velocity, is conceivable. In this embodiment, a mode for measuring the pulse wave propagation speed will be described. Although not particularly mentioned in the following description, the measurement of the pulse wave velocity is performed by detecting the cuff 22 or the like provided for the left and right measurement sites in the subject 10 or the detection result by the pulse wave detector 32 as described above. Accordingly, the measurement is performed individually corresponding to the arteries in the left and right bodies whose symmetry plane is the median plane of the subject 10.

  In the calculation of the pulse wave velocity by the pulse wave velocity information calculating means 96, for example, when a predetermined part (such as the start point of the I sound) that periodically repeats the heart sound detected by the heart sound microphone 48 occurs. A time difference from a point in time when a predetermined waveform (rising point, etc.) that is periodically repeated in each measurement unit discriminated (extracted) by the pulse wave discrimination circuit 40 provided in the pulse wave detection unit 32 corresponding to each cuff is generated. While calculating as the pulse wave propagation time, the pulse wave propagation velocity for each section is calculated from the calculation result and a predetermined distance (arterial length) for each section. In the example shown in FIG. 1, for example, the pulse wave propagation velocity hbPWV between the artery origin and the upper arm artery corresponding to the upper arm cuff 22 corresponds to the thigh cuff 24. The pulse wave velocity hfPWV between the origin and the femoral artery is the pulse wave velocity haPWV between the artery origin and the ankle artery corresponding to the ankle cuff 26. The pulse wave velocity htPWV between the arterial origin and the toe arteries corresponding to the buttocks cuff 28 is between the arterial origin and the carotid artery corresponding to the pressure pulse wave detection device 62. The pulse wave propagation velocity hcPWV is calculated.

Preferably, the pulse wave velocity calculating means 96 preferably circulates in the artery between the measurement sites based on the pulse wave detected from the measurement site around which the cuff 22 or the mounting band 66 is wound. The pulse wave velocity, which is the velocity at which the wave propagates, is calculated. For example, the pulse wave velocity is calculated using the Yoshimura method, which is a well-known pulse wave measurement method. In the Yoshimura method, for example, a carotid pulse wave in which a notch accompanying aortic valve closure appears on the pulse wave is used as a reference. That is, regarding the detection result by the heart sound microphone 48 and the detection result by the pressure pulse wave detection device 62, the heart sound accompanying the aortic closure appears at the head of the second sound of the heart sound, so the time difference from the notch point on the pulse wave ∇t _hc is the pulse wave propagation time between the arterial origin and the carotid artery. By adding this time difference ∇ t _hc and the time difference ∇ t _cf between the carotid artery pulse wave and the pulse wave rising point of the pulse wave velocity measurement portion, the pulse wave propagation time between the artery origin and that portion is obtained. It is done. Therefore, the Yoshimura method can be expressed as a pulse wave propagation time 起 t _hf = ∇t _hc + ∇t _cf between the artery origin and the femoral aorta. When the propagation distance between the arterial origin and the femoral artery is L _hf , the pulse wave velocity hfPWV between the arterial origin and the femoral artery is expressed by the following equation (1): Can be expressed as: Similarly, if the propagation distance between the artery origin and the ankle artery is L _ha , the pulse wave propagation velocity haPWV between the artery origin and the ankle artery is expressed by the following equation (2): Can be expressed as

hfPWV = L _hf / ∇t _hf
= L _hf / (∇t _hc + ∇t _cf ) (1)
haPWV = L _ha / ∇t _ha
= L _ha / (∇t _hc + ∇t _ca ) (2)

Here, a virtual pulse wave propagation velocity vPWV is introduced for the fraction display control by the pulse wave propagation information display control means 98 described later. First, when rewritten as L _ha = L _hc + (L _ha -L _hc ), the above-described equation (2) can be expressed as shown in the following equation (3). Note that ca-vPWV in the equation (3) is a hypothesis between the carotid artery portion and the ankle portion when it is assumed that the pulse wave has propagated from the artery origin to the ankle artery via the carotid artery. Represents the dynamic pulse wave velocity (vPWV).

haPWV = {L _hc + (L _ha -L _hc )} / (∇t _hc + ∇t _ca )
= L _hc / (∇t _hc + ∇t _ca ) + (L _ha -L _hc ) / (∇t _hc + ∇t _ca )
= {L _hc / ∇t _hc } {∇t _hc / (∇t _hc + ∇t _ca )}
+ {(L _ha -L _hc ) / ∇t _ca } {∇t _ca / (∇t _hc + ∇t _ca )}
= HcPWV · ∇ t _hc / ∇ t _ha + ca-vPWV · ∇ t _ca / ∇ t _ha (3)

Here, ∇t _hc / ∇t _ha + ∇t _ca / ∇t _ha = 1, and ∇t _hc / ∇t _ha and ∇t _ca / ∇t _ha are hcPWV and ca− based on the principle of haPWV calculation. It is the contribution rate of vPWV. Assuming that haPWV is obtained by the Yoshimura method or other methods, the pulse wave velocity hfPWV corresponding to the blood flow path existing between the artery origin and the femoral artery is calculated by the same calculation as described above. The pulse wave propagation velocity faPWV corresponding to the blood flow channel existing between the cervical artery and the ankle artery can be expressed as the following equation (4). That is, the contribution rate of the pulse wave velocity of each arterial part included in the average pulse wave velocity of the measurement interval can be obtained as the ratio of the pulse wave propagation time corresponding to that interval. In equation (4), ∇t _ha = ∇t _hf + ∇t _fa .

haPWV = hfPWV · ∇t _hf / ∇t _ha + faPWV · ∇t _fa / ∇t _ha (4)

Further, considering that the pulse wave velocity corresponding to the aorta and the peripheral artery is estimated from the measurement result of the average pulse wave velocity of the whole body, the individual pulse wave velocity is the average value f between the ages. Can be expressed as f = t _hf / ∇t _ha . The arterial length can be simply expressed as a function of the individual's height H as in the following equations (5) to (7). Therefore, the pulse wave propagation speed hfPWV corresponding to the aorta, that is, the pulse wave propagation speed between the artery origin and the femoral artery, and the pulse wave propagation speed faPWV corresponding to the peripheral artery, that is, from the femoral artery to the ankle part. The pulse wave velocity relating to the artery can be estimated as the following equations (8) and (9).

L _ha = f ₁ (H) (5)
L _hf = f ₂ (H) (6)
L _fa = L _ha -L _hf (7)
hfPWV = L _hf / (f · ∇t _ha ) (8)
faPWV = L _fa / {(1-f) · ∇t _ha } (9)

  The pulse wave velocity calculating means 96 preferably calculates (estimates) the pulse wave velocity which is the velocity at which the pulse wave propagates through the artery between the measurement sites as described above. More simply, the pulse wave propagation velocity corresponding to each measurement site may be calculated based on the difference in pulse wave measurement time at each measurement site. For example, the time difference from the detection time of the pulse wave signal corresponding to the thigh cuff 24 to the detection time of the pulse wave signal corresponding to the ankle cuff 26, and the thigh 14 and the ankle portion 16 From this distance, the pulse wave propagation velocity faPWV between the thigh 14 and the ankle 16 is calculated. Further, the time difference from the detection time point of the pulse wave signal corresponding to the ankle cuff 26 to the detection time point of the pulse wave signal corresponding to the toe cuff 28, and the ankle part 16 and the toe part 18 From this distance, the pulse wave propagation time atPWV between the ankle portion 16 and the toe portion 18 is calculated.

FIG. 4 shows the pulse wave propagation time t _hf obtained by assuming a subject of average height using the measurement data of the pulse wave propagation velocity hfPWV regarded as the aorta in subjects of each age that have been published, it is a graph showing the age change of the ratio of the pulse wave propagation time t _ha obtained by assuming the subject average height in the same manner from the measured pulse wave velocity haPWV to. FIG. 5 shows a pulse wave propagation time corresponding to each section, that is, a pulse wave propagation time ∇ t _ha from the artery start to the ankle, and a pulse from the artery start to the thigh for a subject with a height of 165 cm. FIG. 6 is a graph showing the wave propagation time ∇t _hf and the pulse wave propagation time ∇t _fa from the thigh to the ankle part by back calculation. As shown in FIGS. 4 and 5, the change in the pulse wave propagation time ∇t _ha from the 20s to the 60s is substantially dependent on the change in the pulse wave propagation time ∇t _hf. It can be seen that the propagation time ∇t _fa is substantially constant. In addition, it can be seen that the contribution rate of the pulse wave propagation time ∇t _hf to the entire change takes a minimum value in the 60s.

  FIG. 6 is a graph showing changes in pulse wave propagation speed by age, which is the speed at which the pulse wave propagates through the artery between the measurement sites calculated (estimated) as described above. The pulse wave velocity haPWV from the thigh to the ankle is shown by a solid line, and the pulse wave velocity hfPWV from the artery origin to the thigh is shown by a one-dot chain line between the thigh and the ankle The pulse wave propagation speed faPWV is indicated by a two-dot chain line. In the example shown in FIG. 6 as well, the change in the pulse wave velocity haPWV from the 20s to the 60s substantially depends on the change in the pulse wave velocity hfPWV, similar to the relationship shown in FIG. On the other hand, it can be seen that the pulse wave propagation velocity faPWV is substantially constant.

  FIG. 7 is a graph showing changes in pulse wave propagation speed by age, which is the speed at which the pulse wave propagates through the artery between the measurement sites calculated (estimated) as described above, as in FIG. The pulse wave propagation speed haPWV between the arterial origin and the ankle is indicated by a solid line, and the pulse wave propagation speed hbPWV between the arterial origin and the upper arm is indicated by a broken line. As shown in FIG. 7, the change in age of the pulse wave propagation velocity hbPWV between the arterial origin and the upper arm is substantially saturated in the 60s, while the period from the arterial origin to the ankle It can be seen that the pulse wave velocity haPWV continues to rise significantly after the 60s.

  As described above, the trends shown in FIGS. 4 to 7 are considered to be differences due to the time difference regarding the degree of progression of arteriosclerosis according to the type of artery. For example, in the example shown in FIG. 7, the pulse wave propagation velocity hbPWV between the arterial origin and the upper arm shows age dependence close to the aorta, which is an elastic artery, while the arterial origin to the ankle. The pulse wave velocity haPWV between them is considered to indicate the age dependence of the vascular system including the aorta and peripheral arteries.

  FIG. 8 shows an artery related to the pulse wave propagation speed hbPWV between the arterial origin and the upper arm, and FIG. 9 relates to a pulse wave propagation speed haPWV between the arterial origin and the ankle. It is a figure which shows each artery to perform. Further, the reference numbers (ref. No) in FIGS. 8 and 9 indicate the arteries whose approximate positions are shown in FIG. As shown in FIG. 8, the ratio of elastic arteries is high in the arteries from the origin of the artery to the upper arm. The muscular artery length is 24.5 cm (61%). In addition, as shown in FIG. 9, the proportion of muscular arteries is high in the arteries from the origin of the artery to the ankle, and is, for example, a total length of 136 cm in an adult typical example, and its inner elastic artery length 45.2 cm (33 %), And the muscular artery length is 90.8 cm (67%). As shown in these examples, the ratios of the elastic arteries and the muscular arteries are different between the parts of the living body. In other words, it can be said that different types of arterial properties are shown between the parts of the living body.

  Returning to FIG. 3, the pulse wave propagation information display control means 98 displays the pulse wave propagation information measured corresponding to each of a plurality of types of arteries in the subject 10 as the measurement result of the pulse wave propagation information measuring device 20. The display 58 is relatively displayed on the same screen. That is, the pulse wave velocity PWV calculated corresponding to each of a plurality of types of arteries in the subject 10 calculated by the pulse wave velocity calculator 96 is relatively displayed on the same screen of the display 58. Let

  The pulse wave propagation information display control means 98 preferably has a pulse wave propagation speed which is a speed at which the pulse wave propagates through the artery between the measurement sites calculated by the pulse wave propagation speed calculation means 96. The pulse wave velocity corresponding to any one of the aorta, the peripheral artery, and the peripheral arteriole is displayed relatively on the same screen of the display 58. For example, the pulse wave propagation speed hfPWV corresponding to the section from the arterial origin 19 to the thigh 14 and / or the pulse wave propagation speed hbPWV corresponding to the section from the arterial origin 19 to the upper arm 12 in the subject 10. As the pulse wave propagation information corresponding to the aorta, and the pulse wave propagation speed faPWV corresponding to the section from the thigh 14 to the ankle part 16 as the pulse wave propagation information corresponding to the peripheral artery from the ankle part 16 to the footpad. The pulse wave velocity atPWV corresponding to the section up to the part (toe part) 18 is relatively displayed on the same screen of the display 58 as pulse wave propagation information corresponding to the peripheral arteriole. More preferably, the pulse wave propagation information measured corresponding to the arteries in the left and right bodies having the median plane of the subject 10 as a symmetry plane is relatively displayed on the same screen of the display 58.

  FIG. 10 is a view showing an example of a pulse wave velocity fraction displayed on the display 58 by the pulse wave propagation information display control means 98, and the distance from the center of the circle indicates the pulse wave velocity. Yes. In the image shown in FIG. 10, the pulse wave velocity hcPWV corresponding to the section from the arterial origin 19 to the neck 11 in the subject 10 on the hC axis is shown from the arterial origin 19 in the subject 10 on the hF axis. The pulse wave propagation speed hfPWV corresponding to the section to the thigh 14 is represented as the pulse wave propagation speed hbPWV corresponding to the section from the artery origin 19 to the upper arm 12 in the subject 10 on the hB axis. The pulse wave propagation speed faPWV corresponding to the section from the thigh 14 to the ankle 16 in the subject 10 is the pulse wave propagation speed atPWV corresponding to the section from the ankle 16 to the toe 18 in the subject 10 on the aT axis. Respectively. In addition, pulse wave propagation information measured corresponding to an artery in the right half of the body in the right half circle with the median plane of the subject 10 as a symmetry plane, and left in the left half circle with the median plane of the subject 10 as a symmetry plane. The pulse wave propagation information measured corresponding to the artery in the half body is shown. Furthermore, arteries belonging to the large and middle arterial system, arteries belonging to the peripheral arterial system, and arteries belonging to the peripheral arteriole system are indicated by alternate long and short dash lines, and the axes hC, hF, and hB are The display is divided so that fA belongs to the peripheral arterial system and the axis aT belongs to the peripheral arteriole system.

  FIG. 11 is a view showing another example of the pulse wave velocity fraction displayed on the display 58 by the pulse wave propagation information display control means 98. As shown in FIG. In the image shown in FIG. 11, the appropriate range (normal velocity range) for each artery belonging to each type is shown in the pulse wave velocity fraction of FIG. 10 described above. The region shown in gray in the figure is the appropriate range, and the velocity ranges corresponding to normal values (health values) are individually shown in the large / middle arterial system, the peripheral arterial system, and the peripheral arteriole system. In the pulse wave velocity fractionation shown in FIG. 11, the arteries corresponding to any axis are within the appropriate range. For example, the gray range as indicated by Δ on the axis aB corresponding to the right half of the body. If the deviation is outside the range, the pulse wave propagation velocity hbPWV corresponding to the section corresponding to the axis aB, that is, the section from the arterial origin 19 to the upper arm 12 belonging to the large / middle arterial system deviates from the appropriate range. It is considered a thing.

  FIG. 12 is a flowchart for explaining a main part of the pulse wave propagation information display control by the arithmetic and control unit 46, and is repeatedly executed at a predetermined cycle.

  First, in step (hereinafter, step is omitted) S1, it is determined whether or not measurement of pulse wave propagation information is started by performing a predetermined operation or the like. If the determination of S1 is negative, the routine is terminated accordingly. If the determination of S1 is affirmative, the cuff 22 wound around each measurement site of the subject 10 is determined in S2. The respective cuff pressures and the pressure of the pressure pulse wave detection device 62 attached to the neck 11 are controlled to be respectively predetermined pulse wave detection pressures. Next, in S3, a heart sound is detected by the heart sound microphone 48, and a pulse wave signal corresponding to the heart sound for one beat is detected by the pulse wave detecting unit 32 and the pressure pulse wave detecting device corresponding to each measurement site. Detected at 62. Next, in S <b> 4, the cuff pressures of the cuffs 22 and the like wound around the respective measurement sites of the subject 10 and the pressure of the pressure pulse wave detection device 62 attached to the neck 11 are discharged. Next, in S5 corresponding to the operation of the pulse wave velocity calculation means 96, the pulse wave velocity corresponding to the measurement site of the subject 10 is calculated. Next, in S6 corresponding to the operation of the pulse wave propagation information display control means 98, the pulse wave velocity fraction as shown in FIGS. 10 to 11 is displayed on the display 58 in accordance with the calculation result in S5. After being displayed, this routine is terminated. In the above control, S2 and S4 correspond to the operation of the cuff pressure control means 92.

  Thus, according to the present embodiment, based on the pulse wave detected from a predetermined part of the subject 10 that is a living body, the pulse wave propagation information related to the speed at which the pulse wave propagates through the artery of the subject 10. Is a pulse wave propagation information measuring device 20 that measures pulse wave propagation information measured corresponding to each of a plurality of types of arteries in the subject 10 in the same screen, The pulse wave propagation information for each type of artery can be shown in an objectively visible manner. That is, it is possible to provide the pulse wave propagation information measuring device 20 that can relatively evaluate the pulse wave propagation information for each type of artery.

  Further, since the pulse wave propagation information measured corresponding to each of the aorta and the peripheral artery in the subject 10 is relatively displayed in the same screen, the pulse wave propagation information corresponding to each of the aorta and the peripheral artery is displayed. It can be shown objectively visible.

  Further, since the pulse wave propagation information corresponding to the aorta corresponds to the speed at which the pulse wave propagates through the section from the arterial origin 19 to the thigh 14 in the subject 10, it is a practical aspect. Pulse wave propagation information corresponding to the aorta can be obtained.

  Further, since the pulse wave propagation information corresponding to the aorta corresponds to the speed at which the pulse wave propagates through the section from the artery origin 19 to the upper arm 12 in the subject 10, the aorta is practically used. Can be obtained.

  Further, since the pulse wave propagation information corresponding to the peripheral artery corresponds to the speed at which the pulse wave propagates through the section from the thigh 14 to the ankle 16 in the subject 10, Pulse wave propagation information corresponding to the artery can be obtained.

  Further, since the pulse wave propagation information measured corresponding to each of the aorta, peripheral artery, and peripheral arteriole in the subject 10 is displayed relatively in the same screen, the aorta, peripheral artery, and peripheral artery are displayed. The pulse wave propagation information corresponding to each artery can be shown objectively and visually recognizable.

  The pulse wave propagation information corresponding to the peripheral arteriole corresponds to the speed at which the pulse wave propagates through the section from the ankle portion 16 to the toe portion (toe portion) 18 in the subject. Pulse wave propagation information corresponding to peripheral arterioles can be obtained in a typical manner.

  In addition, since the pulse wave propagation information measured corresponding to the arteries in the left and right bodies with the median plane of the subject 10 as a symmetry plane is relatively displayed within the same screen, The pulse wave propagation information for each type can be shown to be objectively visible.

  The preferred embodiments of the present invention have been described in detail with reference to the drawings. However, the present invention is not limited to these embodiments, and may be implemented in other modes.

  For example, in the above-described embodiment, the pulse wave velocity measuring device 20 is a device that performs measurement by winding the cuff 22 or the like around each measurement site in the subject 10, but the present invention is not limited thereto. For example, the apparatus may be an apparatus that performs measurement by adsorbing a sensor to each measurement site using a suction cup or the like. That is, the present invention provides a pulse wave propagation information measuring device capable of measuring pulse wave propagation information related to the speed at which a pulse wave propagates through an artery of the living body based on a pulse wave detected from a predetermined site in the living body. It is widely applied to.

  In the above-described embodiment, the pulse wave velocity measuring device 20 detects pulse waves at the neck 11, the upper arm 12, the thigh 14, the ankle 16, and the toe 18 of the subject 10. Then, the pulse wave propagation information corresponding to the detection result is displayed, but the measurement site is at least better than this, for example, the upper arm part 12, the ankle part 16, and the toe part 18 of the subject 10, respectively. The pulse wave may be detected and pulse wave propagation information corresponding to each of a plurality of types of arteries may be displayed according to the detection result. Also in such an aspect, the pulse wave propagation speed corresponding to the aorta corresponding to the speed at which the pulse wave propagates through the section from the artery origin 19 to the upper arm 12 in the subject 10, the ankle 16 to the footpad The pulse wave propagation speed corresponding to the peripheral arteriole corresponding to the speed at which the pulse wave propagates through the section up to 18 can be displayed in comparison on the same screen on the display 58.

  Further, in the above-described embodiment, the pulse wave velocity measuring device 20 corresponds to the arteries in the left and right bodies with the median plane of the subject 10 as the symmetry plane, respectively, and the individual cuffs 22 and the like or the pulse wave detector 32. However, it may be provided with only a device corresponding to the half body. In such an aspect, preferably, measurements corresponding to the arteries in the left and right bodies having the midline of the subject 10 as the symmetry plane are individually performed at predetermined time intervals, and the measurement results are aggregated. Are displayed on the same screen on the display 58.

  In addition, although not illustrated one by one, the present invention is implemented with various modifications within a range not departing from the gist thereof.

It is a block diagram explaining the structure of the pulse wave propagation information measuring apparatus which is one Example of this invention. It is a figure explaining the structure of the pressure pulse wave detection apparatus with which the pulse wave propagation information measuring apparatus of FIG. 1 was equipped. It is a functional block diagram explaining the principal part of the control function with which the calculation control apparatus in the pulse wave propagation information measuring apparatus of FIG. 1 was equipped. Using the published measurement data of the pulse wave velocity regarded as the aorta in subjects of each age, the pulse wave propagation time obtained assuming a subject of average height and the actually measured pulse wave propagation It is a graph which shows the change according to the age of ratio with the pulse wave propagation time obtained by assuming the test subject of average height similarly from speed. FIG. 4 shows the pulse wave propagation time from the arterial origin to the ankle, the pulse wave propagation time from the arterial origin to the thigh, and the pulse wave propagation time from the thigh to the ankle for a subject with a height of 165 cm. It is a graph shown by reversely calculating from the graph shown in FIG. It is a graph which shows the change according to the age of the pulse wave propagation speed which is the speed at which the pulse wave propagates in the artery between the respective measurement sites calculated by the method used in this example, from the artery origin to the ankle The pulse wave velocity between the thigh and the ankle is shown by the dashed line and the pulse wave velocity between the thigh and the ankle is shown by the solid line. Each is indicated by a two-dot chain line. It is a graph which shows the change according to the age of the pulse wave propagation speed which is the speed at which the pulse wave propagates in the artery between the respective measurement sites calculated by the method used in this example, from the artery origin to the ankle The pulse wave propagation speed relating to the interval between the arterial origin and the upper arm is indicated by a solid line, and the pulse wave propagation speed relating to the upper arm part is indicated by a broken line. It is a figure which shows the artery relevant to the pulse-wave propagation speed concerning from an artery origin part to an upper arm part. It is a figure which shows the artery relevant to the pulse-wave propagation speed concerning from an artery origin part to an ankle part. It is a figure which shows an example of the pulse wave velocity fraction displayed on a display device by the pulse wave propagation information measuring device of FIG. 1, and the distance from the center of the circle indicates the pulse wave velocity. It is a figure which shows another example of the pulse wave velocity fraction displayed on a display by the pulse wave propagation information measuring apparatus of FIG. 1, and is suitable for every artery which belongs to each kind in the pulse wave velocity fraction of FIG. The range is also shown. It is a flowchart explaining the principal part of the pulse wave propagation information display control by the calculation control apparatus in the pulse wave propagation information measuring apparatus of FIG. It is a figure which shows each artery of the biological body corresponding to the reference number in FIG.

Explanation of symbols

10: Subject (living body)
12: Upper arm 14: Thigh 16: Ankle 18: Toe (toe)
19: Arterial origin 20: Pulse wave propagation information measuring device

Claims (8)

A pulse wave propagation information measuring device for measuring pulse wave propagation information related to a speed at which a pulse wave propagates through an artery of the living body based on a pulse wave detected from a predetermined site in the living body,
A pulse wave propagation information measuring apparatus that displays pulse wave propagation information measured corresponding to each of a plurality of types of arteries in the living body relatively within the same screen.   The pulse wave propagation information measuring device according to claim 1, wherein the pulse wave propagation information measured corresponding to each of the aorta and the peripheral artery in the living body is relatively displayed on the same screen.   The pulse wave propagation information measuring device according to claim 2, wherein the pulse wave propagation information corresponding to the aorta corresponds to a speed at which the pulse wave propagates through a section from the arterial origin to the thigh in the living body. .   The pulse wave propagation information measuring device according to claim 2, wherein the pulse wave propagation information corresponding to the aorta corresponds to a speed at which the pulse wave propagates through a section from the arterial origin to the upper arm in the living body.   The pulse wave propagation information corresponding to the peripheral artery corresponds to a speed at which the pulse wave propagates through a section from the thigh to the ankle in the living body. Pulse wave propagation information measuring device.   The pulse wave propagation information measured corresponding to each of the aorta, the peripheral artery, and the peripheral arteriole in the living body is displayed relatively in the same screen. Pulse wave propagation information measuring device.   The pulse wave propagation information measuring device according to claim 6, wherein the pulse wave propagation information corresponding to the peripheral arteriole corresponds to a speed at which the pulse wave propagates through a section from the ankle part to the toe part in the living body. .   The pulse wave propagation information measured corresponding to the arteries in each of the left and right bodies with the median plane of the living body as a symmetry plane is displayed relatively in the same screen. The pulse wave propagation information measuring device described.