JP5993226B2 - Pulse wave propagation information measuring device - Google Patents

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.

  A pulse wave propagation information measuring device for measuring pulse wave propagation information related to a velocity (pulse wave propagation velocity) 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 Are known. As one aspect thereof, a technique for evaluating the degree of arteriosclerosis based on pulse wave propagation information by utilizing the influence of the degree of arteriosclerosis of a living body on the pulse wave propagation information is known. In the measurement of such pulse wave propagation information, for example, pulse waves are detected at two points in the living body to be measured, and the pulse wave propagation velocity is measured from the distance between the two points and the time difference between the pulse wave propagations. 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, in order to measure the pulse wave propagation information, for example, the pulse wave propagation velocity, basically, it is necessary to detect the pulse wave at two points at both ends of the section to be measured by the living body. Depending on the detection site, it may be difficult to detect the pulse wave. For example, in some cases, it is difficult for a person to mount a pulse wave detector, a cuff, or other detector such as a pulse wave measurement at a site such as an abdominal aorta or femoral artery where the pulse oscillates. In addition, there is a problem that it is necessary to ensure a measurement environment at the time of medical examination.

  The present invention has been made against the background of the above circumstances, and its purpose is to correspond to a section to be measured without directly detecting a pulse wave at one end of the section to be measured by a living body. An object of the present invention is to provide a pulse wave propagation information measuring device capable of obtaining the pulse wave propagation information.

The gist of the first invention for achieving the above object is: (a) Pulse wave propagation information for measuring pulse wave propagation information that is a pulse wave propagation time or a pulse wave propagation speed between two parts of a living body artery. (B) pulse wave propagation information corresponding to a section from the first part of the artery to a second part downstream of the first part, and from the first part to the first part. Based on the pulse wave propagation information corresponding to the section from the artery between the first part and the second part downstream to the third part on the artery branched from the first part, the first part to the first part Pulse wave propagation information corresponding to the section from the fourth part to the second part and pulse wave propagation information corresponding to the part to the fourth part located in the middle of the path of the artery between the part and the second part One or both of the information and the information are calculated.

  In this way, it is possible to obtain pulse wave propagation information corresponding to the measurement target section having the fourth part as one end without directly detecting the pulse wave at the fourth part. For example, this is particularly useful when it is difficult to directly detect a pulse wave at the fourth region.

Here, the gist of the second invention is the pulse wave propagation information measuring device according to the first invention, wherein the first part is an aorta starting part of the living body , and the second part is the living body. an ankle portion, said third portion is the upper arm of the living body, the fourth site is characterized by a thigh of the body. In this way, it is possible to detect pulse waves and the like at the aorta starting portion of the living body, the upper arm portion of the living body , and the ankle portion of the living body, which are easy to detect the pulse waves and the like that are the basis for obtaining the pulse wave propagation information. By detecting, it is possible to obtain pulse wave propagation information corresponding to a measurement target section having a thigh that is often difficult to detect a pulse wave as one end.

  The gist of the third invention is the pulse wave propagation information measuring device according to the first invention or the second invention, wherein (a) a pulse corresponding to a section from the first part to the second part. The wave propagation information is a first pulse wave propagation time during which a pulse wave propagates from the first part to the second part, and (b) a pulse wave corresponding to a section from the first part to the third part. Propagation information is a second pulse wave propagation time during which a pulse wave propagates from the first part to the third part, and (c) the first pulse wave propagation time and the second pulse wave propagation time. Based on the difference between the pulse wave propagation speed included in the pulse wave propagation information corresponding to the section from the first part to the fourth part and the pulse wave corresponding to the section from the fourth part to the second part. One or both of the pulse wave velocity included in the propagation information is calculated. In this way, it is possible to obtain the pulse wave velocity corresponding to the measurement target section having the fourth part as one end without directly detecting the pulse wave at the fourth part.

A gist of the fourth invention is the pulse wave propagation information measuring device according to the third invention , wherein the pulse wave propagation time between the aortic root of the living body and another part is calculated. Includes measuring a provisional pulse wave propagation time from a predetermined characteristic time point in an electrocardiogram induction signal or a heart sound signal as a measurement start point, and the provisional pulse wave so that the measurement start point can be regarded as a cardiac aortic valve opening time point. A value obtained by correcting the wave propagation time based on the time difference between the predetermined characteristic time point and the aortic valve opening time point is set as a pulse wave propagation time between the aortic origin and another part. In this way, even when it is difficult to directly detect the aortic valve opening time of the heart, it is possible to accurately obtain the pulse wave propagation time between the aortic root and other parts. is there.

  The gist of the fifth invention is the pulse wave propagation information measuring device according to any one of the first invention to the fourth invention, corresponding to a section from the first part to the second part. Measured or calculated corresponding to two types of two parts including pulse wave propagation information calculated based on the pulse wave propagation information and the pulse wave propagation information corresponding to the section from the first part to the third part. The pulse wave propagation information is displayed relatively in the same screen. In this way, pulse wave propagation information for each type of artery can be shown objectively and comparatively comparable. 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.

It is a block diagram for demonstrating the structure of the pulse-wave propagation information measuring apparatus which is one Example of this invention. It is the figure which represented the electrocardiogram induction signal typically in order to explain each waveform contained in the electrocardiogram induction signal detected in the pulse wave propagation information measuring device of FIG. It is a figure for demonstrating 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 for demonstrating the principal part of the control function with which the calculation control apparatus contained in the pulse wave propagation information measuring apparatus of FIG. 1 was equipped. It is a time chart showing the electrocardiogram induction signal, the heart sound signal, and the aorta waveform in the subject of FIG. It is the figure which illustrated the relationship between precursor time and heart rate in the heart of a living body (human). The time difference between each feature point of the electrocardiogram induction signal and the heart sound signal measured experimentally in advance for deriving the calculation formula used by the pulse wave velocity calculation means of FIG. 4 to perform the PEP correction processing is displayed. FIG. The pulse wave velocity haPWV, hfPWV, faPWV calculated based on the measurement results such as the pulse wave measured as shown in FIG. 1 for a plurality of subjects having different ages, and the age of the subject It is a figure showing the relationship. FIG. 9 is a table showing a relationship between a human age and a pulse wave velocity hfPWV cited from a predetermined document 1 and a predetermined document 2 different from the document 1 in order to perform data comparison with FIG. 8. . 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. 3 is a flowchart for explaining a main part of pulse wave propagation information display control by an arithmetic and control unit included in the pulse wave propagation information measuring apparatus of FIG. 1.

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

  FIG. 1 is a block diagram for explaining the configuration of a pulse wave propagation information measuring apparatus 20 according to an embodiment of the present invention. As shown in FIG. 1, the pulse wave propagation information measuring device 20 of the present embodiment includes a cervical region and an upper arm as measurement portions of a pulse wave and a blood pressure value for calculating a pulse wave velocity related value (pulse wave propagation information). Part, ankle part, and toe part are selected. In the pulse wave propagation information measuring apparatus 20 as described above, the subject to be measured takes one of the prone position, the lateral position, and the supine position so that each of the measurement parts has substantially the same height. The measurement described in detail below is performed in the state. 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 is a portion corresponding to a so-called neck, which connects the head and trunk of a subject who is a living body (human) to be measured. The upper arm portion is a portion corresponding to a so-called second arm portion between the shoulder joint and elbow joint of the subject. The thigh is a portion between the waist and the knee of the subject, that is, a portion having a thighbone, a portion corresponding to a so-called thigh, and preferably a femoral artery. The ankle portion is a part of the subject's foot (leg) above the heel. Further, the toe portion is a peripheral portion of the subject's foot, preferably the 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 arms. The ankle cuffs 26R and 26L (hereinafter simply referred to as the ankle cuff 26 unless otherwise specified) for winding around the left and right ankles, and the left and right toes, respectively. For toe part cuffs 28R and 28L (hereinafter simply referred to as toe part cuff 28 unless otherwise specified). These upper arm cuff 22, ankle cuff 26, and toe cuff 28 (hereinafter referred to as cuff 22, etc. unless otherwise specified) are compression bands that compress the part to be wound, Preferably, a soft polyvinyl chloride bag is provided in a belt-like outer bag made of a non-extensible material such as cloth or polyester resin. The upper arm cuff 22, the ankle cuff 26, and the toe cuff 28 are respectively connected to the corresponding pulse wave detectors 32UR and 42AR (hereinafter simply referred to as “pulses” unless otherwise specified). Connected to the wave detector). The ankle part and the toe part are not measured at the same time, and measurement is performed by switching the measurement site. Since these pulse wave detectors preferably have the same configuration, the configuration thereof will be described in detail below with the pulse wave detector 32UR corresponding to the upper right arm as shown in FIG. 1 as an example. To do.

As shown in FIG. 1, the upper arm cuff pulse wave detector 32UR includes an exhaust valve 34, a pressure sensor 36, and an air pump 44. The supply / exhaust path is an exhaust valve 34, an air pump 44, and a pressure. The sensor 36 is connected. The exhaust 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 pulse wave detector 42AR for ankle cuff or toe cuff corresponds to the measurement of the ankle or toe, and the air of the 3-port solenoid valve 38 is operated by the solenoid valve drive circuit 37 based on the control signal of the arithmetic control device 59. The system output is connected to the ankle cuff 26 or toe cuff 28.

The pressure sensor 36 detects the pressure in the cuff 22 and the like, and supplies a pressure signal SP _b representing the pressure to the arithmetic control device 59 via the A / D conversion circuit 50.

  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 thoracic epidermis corresponding to the subject's aortic root, and detects and outputs a heart sound signal PCG representing the heart sound. The heart sound signal PCG output from the heart sound microphone 48 is shaped by the heart sound diagram circuit 47 and supplied to the arithmetic control device 59 via the A / D conversion circuit 50. Since the heart sound represented by the heart sound signal PCG is a heart beat synchronization signal generated in synchronization with the heart beat of the subject, the heart sound microphone 48 that outputs the heart sound signal PCG functions as a heart beat synchronization signal detection device.

  The pulse wave propagation information measuring device 20 includes an electrocardiographic electrode sensor 52. The electrocardiographic electrode sensor 52 is disposed at a predetermined wearing position on the chest epidermis, and sequentially detects and outputs an electrocardiographic induction signal (electrocardiographic signal) ECG. The electrocardiographic induction signal ECG is A / D converted and supplied to the arithmetic control device 59 as a signal synchronized with the heartbeat synchronization signal. For example, if the waveform for one period is schematically represented as shown in FIG. 2, the electrocardiographic induction signal ECG is represented in the order of P wave, Q wave, R wave, S wave, T wave, and U wave. Sequentially detected. For example, from the ECG signal ECG, the ECG signal ECG is differentiated, and the time position of the positive or negative peak of each wave, specifically, the Q time point that is the peak time of the Q wave, the R wave R point, which is the peak time, and S point, which is the peak time of the S wave, are detected.

  Returning to FIG. 1, the arithmetic and control unit 59 is constituted by a so-called microcomputer having a CPU, a ROM, a RAM, an I / O port and the like (not shown). The CPU outputs a driving signal from the I / O port by executing signal processing while using a temporary storage function of the RAM in accordance with a program stored in advance in the ROM, so that the air pump 44 and the pulse wave detection unit The exhaust valve 34 is controlled, and various controls such as pulse wave velocity calculation control and pulse wave information display control described later are executed. The pulse wave propagation information measuring device 20 stores a display 53 that displays a predetermined video (image) in accordance with an output from the arithmetic control device 59, and various types of information related to control by the arithmetic control device 59. A storage device 60 (see FIG. 4).

  The pulse wave propagation information measuring device 20 includes a pressure pulse wave detection device 66 for detecting a pulse wave of the neck (carotid artery) in the subject. FIG. 3 is a diagram for explaining the configuration of such a pressure pulse wave detection device 66. As shown in FIG. 3, the pressure pulse wave detection device 66 is pressed against the subject's carotid artery to non-invasively detect the pressure pulse wave in the carotid artery. A vibration sensor 68 is provided and is attached to the subject's neck by an attachment band.

  When the pressure pulse wave detecting device 66 is pressed on the carotid artery on the body surface in the neck of the subject, the low-frequency vibration sensor 68 generates pressure vibration generated from the carotid artery and transmitted to the body surface. A wave, that is, a pressure pulse wave is detected, and a pressure pulse wave signal representing the pressure pulse wave is supplied to the pulse wave circuit 65. The pulse wave circuit 65 extracts (discriminates) a signal (hereinafter referred to as a carotid artery wave signal) representing a carotid artery wave included in the pressure pulse wave signal by a low-pass filter (not shown), and corresponds the carotid artery signal to the carotid artery. The pulse wave signal is supplied to the arithmetic and control unit 59 through the A / D conversion circuit 50.

  FIG. 4 is a functional block diagram for explaining a main part of the control function provided in the arithmetic and control unit 59. As shown in FIG. 4, the arithmetic and control unit 59 includes a cuff pressure control unit 62 that is a cuff pressure control unit, a blood pressure value determination unit 58 that is a blood pressure value determination unit, and a pulse wave propagation that is a pulse wave propagation speed calculation unit. The velocity calculation means 55 and the pulse wave propagation information display control means 63 which is a pulse wave propagation information display control part are functionally provided. In FIG. 4, the upper arm cuff 22 (upper right arm cuff 22 </ b> R) of the configurations corresponding to the upper arm cuff 22, ankle cuff 26, and toe cuff 28 is used. Only the corresponding configuration is illustrated. Further, the pulse wave propagation speed PWV, which is the speed at which the pulse wave propagates through the artery, is specifically shown by specifying between two parts of the living body. In this embodiment, when the two parts are specified and indicated, the reference numerals indicating those parts are attached to PWV and displayed, for example, from the aortic root (indicated by h) to the femoral artery ( The pulse wave velocity PWV corresponding to the section up to (indicated by f) is expressed as hfPWV, and the pulse wave velocity PWV corresponding to the section from the femoral artery to the ankle (indicated by a) is expressed as faPWV. The pulse wave velocity PWV corresponding to the section from the aortic origin to the ankle is expressed as haPWV, and the pulse wave velocity PWV corresponding to the section from the aortic origin to the upper arm (indicated by b) is Expressed as hbPWV. The aortic origin corresponds to the first part of the present invention, and the ankle part is a part downstream from the aortic origin and corresponds to the second part of the present invention. The upper arm part is a part on the artery downstream from the aorta starting part and branched from the artery between the aortic starting part and the ankle part, and corresponds to the third part of the present invention. The thigh is a part located in the middle of the path of the artery between the aortic root and the ankle part, and corresponds to the fourth part of the present invention.

In the blood pressure measurement, the cuff pressure control means 62 controls the air pump 44 and each exhaust valve 34 connected to the air pump 44 so that the cuff pressure in each of the cuffs 22 and the like is set to a predetermined target pressure value P. The pressure is rapidly increased to _CM (for example, a pressure value of about 180 mmHg for the upper arm cuff 22 and a pressure value of about 240 mmHg for the ankle cuff 26), and then the pressure is gradually decreased at a speed of about 5 mmHg / sec. In detecting the pulse wave, the cuff pressure in each of the cuffs 22 and the like is increased to a predetermined pulse wave detection pressure by controlling the air pump 44 and the exhaust valves 34 connected to the air pump 44. After that, 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 sufficient signal intensity, for example, 50 mmHg.

  The blood pressure value determining means 58 may be based on the change in the amplitude of the pulse wave signals 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 62. Using a known oscillometric method, a systolic blood pressure value and a diastolic blood pressure value, which are blood pressure values BP at the measurement site corresponding to each cuff, are determined. The blood pressure value determined by the blood pressure value determining means 58 is stored in, for example, the storage device 60 and displayed on the display unit 53 according to a predetermined operation.

  The pulse wave velocity calculating means 55 includes a pulse wave detected from a measurement site around which the cuff 22 and the like are wound, a heart sound signal PCG detected by the heart sound microphone 48, and a heart detected by the electrocardiographic electrode sensor 52. Based on the electric induction signal ECG and the carotid artery SN detected by the pressure pulse wave detector 66, the pulse wave propagation as pulse wave propagation information related to the speed of the pulse wave propagating in the artery of the subject. Calculate the speed PWV. Specifically, the speed at which the pulse wave propagates between the aortic root, that is, the heart, and each measurement site, for example, the site where the cuff 22 or the like is mounted or the site where the pressure pulse wave detection device 66 is mounted. (Pulse wave propagation velocity PWV) is calculated. Here, as the pulse wave propagation information related to the pulse wave propagation speed PWV between the two parts of the subject, the pulse wave propagation time PWT, which is the time during which the pulse wave propagates through the artery between the two parts of interest, and the artery The pulse wave propagation speed PWV, which is the speed at which the pulse wave propagates, is exemplified. In this embodiment, an aspect of measuring the pulse wave propagation speed PWV will be described. Although not specifically mentioned in the following description, the measurement of the pulse wave propagation speed PWV is based on the detection result by the cuff 22 or the like or the pulse wave detection unit provided corresponding to the left and right measurement sites in the subject 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.

  In the calculation of the pulse wave propagation speed PWV by the pulse wave propagation speed information calculating means 55, for example, when a predetermined waveform that periodically repeats the electrocardiographic induction signal ECG or the heart sound signal PCG (see FIG. 5) occurs (for example, heart sound) Between the start time of the first sound and the time point Q in FIG. 2) and the time point when the pulse wave waveform periodically repeated by each measurement unit obtained by the pulse wave detection unit corresponding to each cuff is generated (for example, the rising point). The time difference is calculated as the pulse wave propagation time PWT, and the pulse wave propagation velocity PWV for each section is calculated from the calculation result and a predetermined distance (arterial length) for each section. The pulse wave propagation velocity PWV is calculated by dividing the distance between two parts to be measured, that is, the blood vessel length (arterial length) by the pulse wave propagation time PWT. The blood vessel length can be calculated based on the height H of the subject from a predetermined empirical formula, for example. In the example shown in FIG. 1, the pulse wave propagation speed hcPWV between the aortic root and the carotid artery is based on the electrocardiographic induction signal ECG or the heart sound signal PCG and the pulse wave signal SN from the pressure pulse wave detection device 66. The pulse wave velocity hbPWV between the aortic origin and the upper arm is calculated based on the electrocardiographic induction signal ECG or the heart sound signal PCG and the pulse wave signal from the upper arm cuff 22, and the aortic origin The pulse wave velocity haPWV between the head and ankle is calculated based on the electrocardiographic induction signal ECG or heart sound signal PCG and the pulse wave signal from the ankle cuff 26, and the aortic root and toe The pulse wave velocity htPWV between the toe arterial part is calculated based on the electrocardiographic induction signal ECG or the heart sound signal PCG and the pulse wave signal from the toe part cuff 28.

  When calculating the pulse wave propagation speed PWV as described above, the pulse wave propagation speed calculating means 55 calculates the heart wave first I when measuring the pulse wave propagation time PWT between the aortic root and other parts. The start point of the sound or the like may be used as the measurement start point of the pulse wave propagation time PWT. However, in order to accurately measure the pulse wave propagation time PWT, the aortic valve opening time Ps of the heart, that is, the pre-ejection period PEP (pre-ejection period) It is desirable that the measurement start point is the end point Ps (also referred to as the first half of ejection). However, the end point Ps of the precursor time PEP is often difficult to detect directly. Therefore, the pulse wave velocity calculation means 55 measures the provisional pulse wave propagation time PWT ′ using the Q point at which detection is easy, that is, the start point of the precursor time PEP (see FIGS. 2 and 5) as the measurement start point, and the precursor time. By calculating the PEP and subtracting the precursor time PEP from the provisional pulse wave propagation time PWT ′, the pulse wave propagation time PWT (= PWT′−PEP) between the aortic root and the other part is calculated. Perform PEP correction processing to calculate. Then, the pulse wave velocity PWV is calculated based on the pulse wave propagation time PWT after the PEP correction process. FIG. 5 is a diagram for explaining the PEP correction process.

FIG. 5 is a time chart showing the electrocardiographic induction signal ECG, the heart sound signal PCG, and the aortic waveform. The precursor time PEP and the left ventricular ejection time LVET (Left Ventricular Ejection Time; sometimes referred to simply as ejection time ET in this embodiment) shown in FIG. Under the influence of HR, PEP / LVET (= α) is known to be affected by cardiac function without being affected by heart rate HR. For example, the precursor time PEP is affected by the heart rate HR as shown in FIG. Therefore, the pulse wave velocity calculating means 55 uses the time Q, time R, heart sound I and sound II obtained from the electrocardiographic induction signal ECG and the heart sound signal PCG, and calculates the progenitor time PEP as an electrocardiogram and electrocardiogram. The QII time obtained from the information is estimated by the average value theorem. Specifically, the precursor time PEP is calculated by the following formula (11). The formula (11) is defined as t ₁ = PEP and t ₂ = LVET, and is derived as follows. In order to derive the time difference, the time difference between the feature points of the electrocardiographic induction signal ECG and the heart sound signal PCG measured experimentally in advance as shown in FIG. 7 is used.
From FIG. 5, the QII time is the sum of the PEP time (precursor time) and the ET time (= LVET), and is represented by the following formula (1).
QII = t ₁ + t ₂ (1)
The ratio α between PEP and LVET is introduced.
α = t ₁ / t ₂ (2); ˜91 / 285 = 0.31
PEP is expressed by QII time and α.
t ₁ = QII−t ₂ (3)
t ₁ = QII−t ₁ / α (4)
t ₁ × (1 + 1 / α) = QII (5)
t ₁ = QII × {α / (α + 1)} (6)
Accordingly, the time PEP from the Q wave to the rising point Ps of the pulse wave at the beginning of the aorta is expressed by the following equation.
PEP = {α / (α + 1)} × QII (7)
The boundary value of the QII time is set to QII ₀ , and the QII time is displayed as QII ₀ and its difference ΔQII.
QII = QII ₀ + ΔQII (8)
Then PEP is expressed by the following equation.
PEP = {α / (α + 1)} × QII ₀ × (1 + ΔQII / QII ₀ ) (9)
PEP is the time determined by the total system of the heart and the arterial system connected to it.
PEP ₀ = {α / (α + 1)} × QII ₀ (10)
PEP can be expressed in the form of the following average value theorem with QII as a variable.
PEP = PEP ₀ × (1 + ΔQII / QII ₀ ) (11)
Here, PEP ₀ was set to the standard value of PEP (= 91 msec) as described below, and the boundary value QII ₀ was statistically determined.
PEP ₀ = 91 [msec]
QII ₀ = 402 [msec]
PWT '= PWT + PEP
= PWT + 91 × (1 + ΔQII / 402) (12)
When converted to the ECG R-wave standard,
RPs = PEP-QR
= 91 × (1 + ΔQII / 402) −QR (13)
On the other hand, the QII time shows heart rate dependency, and the relationship is expressed by the following equation with the proportionality constant being k from the RR interval of the connected pulse wave.
QII = k × RR ^1/2 (14)
FIG. 6 shows the heart rate dependence of the PEP time.

The above formulas (1) to (14) will be described. QII in the above formula (1) is the time from the Q point when the Q wave is generated to the start point Pn of the second sound of the heart sound. The equation (2) is an equation defining α, and the numerical value “91/285” specifically assigned to the equation (2) is a value quoted from FIG. QII ₀ is a constant set experimentally, and is a value of QII experimentally measured in the state of FIG. The pulse wave velocity calculating means 55 calculates the precursor time PEP by the above equation (11). When the provisional pulse wave propagation time PWT ′ is measured as the Q wave reference, the relationship between the provisional pulse wave propagation time PWT ′ and the finally calculated pulse wave propagation time PWT is expressed by the above equation (12). ). In the present embodiment, the provisional pulse wave propagation time PWT ′ is measured as a Q wave reference. However, the R wave reference may be used. The time RPs from a certain R time point to the pulse wave rising time point Ps needs to be calculated, and the RPs can be calculated by the above equation (13) based on the time difference QR between the measured Q time point and the R time point.

As described above, the pulse wave velocity calculating means 55 calculates the pulse wave velocity haPWV, hbPWV, etc., but the pulse wave velocity hfPWV and the large wave wave velocity corresponding to the section from the aortic origin to the femoral artery of the thigh are large. The pulse wave velocity faPWV corresponding to the section from the femoral artery to the ankle of the thigh is also calculated. However, as shown in FIG. 1, no arterial pulse wave is detected in the thigh. Therefore, the pulse wave velocity calculating means 55 is based on the pulse wave velocity haPWV, hbPWV or the data measured for calculating them, specifically, in the section from the aortic origin to the ankle. Based on the corresponding pulse wave propagation time haPWT and the pulse wave propagation time hbPWT corresponding to the section from the aortic origin to the upper arm, the pulse corresponding to the section from the aortic origin to the femoral femoral artery A wave propagation velocity hfPWV and a pulse wave propagation velocity faPWV corresponding to a section from the femoral artery to the ankle of the thigh are calculated. Specifically, the pulse wave velocity calculation means 55 first starts the aorta based on the height H of the subject from the following formulas (18) to (21) which are experimental formulas obtained experimentally in advance. Blood vessel length (arterial length) L_hb from the upper arm to the upper arm, blood vessel length L_ha from the aortic origin to the ankle, blood vessel length L_hf from the aortic origin to the femoral artery of the thigh, and thigh The blood vessel length L_fa from the femoral artery to the ankle is calculated. The unit of height H in the formulas (18) to (21) is “cm”.
L_hb = 0.2188 × H−1.9534 (18)
L_ha = 0.8143 × H + 12.866 (19)
L_hf = 0.5657 × H−17.843 (20)
L_fa = 0.2486 × H + 30.709 (21)

The pulse wave propagation velocity calculating means 55 is a first pulse wave propagation time haPWT corresponding to a section from the aortic origin to the ankle, measured based on the pulse wave signal from the ankle cuff 26. The pulse wave propagation time haPWT and the second pulse wave propagation time hbPWT corresponding to the section from the aortic origin to the upper arm measured based on the pulse wave signal from the upper arm cuff 22 Based on hbPWT and the blood vessel lengths L_fa and L_hb, a pulse wave propagation time hfPWT corresponding to a section from the aortic root to the femoral artery of the thigh is calculated from the following equation (22). In the following formulas (22) to (25), the pulse wave propagation time hfPWT is represented by t_hf, the pulse wave propagation time haPWT is represented by t_ha, the pulse wave propagation time hbPWT is represented by t_hb, The pulse wave propagation time faPWT corresponding to the section from the femoral artery to the ankle is expressed by t_fa. When calculating the pulse wave propagation time hfPWT (= t_hf) from the following equation (22), the pulse wave velocity calculating means 55 calculates the pulse wave propagation velocity hfPWV from the following equation (23). Further, based on the pulse wave propagation time haPWT (= t_ha) and the pulse wave propagation time hfPWT (= t_hf) obtained from the following expression (22), the pulse wave propagation time faPWT (= t_fa) is calculated, and the pulse wave propagation velocity faPWV is calculated from the following equation (25) based on the calculated pulse wave propagation time faPWT. In short, as can be seen from the following equation (22), the pulse wave velocity calculating means 55 calculates the first pulse wave propagation time haPWT (= t_ha) and the second pulse wave propagation time hbPWT (= t_hb). Based on the difference (= t_ha−t_hb), the pulse wave velocity hfPWV corresponding to the section from the aortic root to the femoral artery of the thigh and the section from the femoral artery to the ankle of the thigh The pulse wave propagation velocity faPWV is calculated.
t_hf = t_ha−0.9 × L_fa × (t_ha−t_hb) / (L_ha−L_hb) (22)
hfPWV = L_hf / t_hf (23)
t_fa = t_ha−t_hf (24)
faPWV = L_fa / t_fa (25)

Here, how the equation (22) is derived will be described. The pulse wave propagation time hfPWT (= t_hf) corresponding to the section from the aortic origin to the ankle and the section from the aortic origin to the femoral artery of the thigh is expressed by the following equation (26). . When the pulse wave propagation time PWT per unit blood vessel length in the section from the femoral artery to the ankle of the thigh is set to t01_fa, the following equation (26) becomes the following equation (27). Further, when t01_fa is expressed by using a difference (= t_ha−t_hb) between the first pulse wave propagation time haPWT and the second pulse wave propagation time hbPWT, the following equation (28) is obtained. t01_fa is given by the following formula (28). The equation (22) is derived by combining the equation (28) with the following equation (27). The right side of the following formula (28) is multiplied by “0.9”, which means that the pulse wave propagation velocity PWV is the blood vessel cross-sectional area A, blood density ρ, and blood vessel compliance K as shown in the following formula (29). And the right side of the following equation (28) needs to be corrected by the fact that the blood vessel cross-sectional area between the femoral artery and the ankle and the blood vessel cross-sectional area of the brachial artery are different from each other. Therefore, “0.9” is the correction coefficient Xam for the correction.
t_hf = t_ha−t_fa (26)
t_hf = t_ha−L_fa × t01_fa (27)
t01_fa = 0.9 × (t_ha−t_hb) / (L_ha−L_hb) (28)
PWV = (A / (ρ × K)) ^1/2 (29)

  FIG. 8 shows pulse wave propagation speeds haPWV calculated by the pulse wave propagation speed calculation means 55 based on the measurement results such as pulse waves measured as shown in FIG. 1 for a plurality of subjects having different ages. It is a figure showing the relationship between hfPWV and faPWV and the age of a subject. The straight line LINEha shown in FIG. 8 is obtained by the regression analysis using the least square method or the like, and the pulse wave propagation velocity haPWV obtained based on a plurality of calculation data of the pulse wave propagation velocity haPWV (x mark in FIG. 8). And a regression line showing the relationship between the age. The straight line LINEhf is a regression line showing the relationship between the pulse wave velocity hfPWV and the age obtained based on a plurality of calculation data (circles in FIG. 8) of the pulse wave velocity hfPWV by the regression analysis. It is. Further, the straight line LINEfa is a regression line showing the relationship between the pulse wave propagation speed faPWV and the age obtained based on a plurality of calculation data (Δ mark in FIG. 8) of the pulse wave propagation speed faPWV by the regression analysis. It is. FIG. 9 is a table showing the relationship between the age of a person cited from a predetermined document 1 and a predetermined document 2 different from the document 1, and the pulse wave velocity hfPWV. When the straight line LINEhf in FIG. 8 and the table in FIG. 9 are compared with each other, the relationship between the pulse wave velocity hfPWV and the age of the human (subject) is sufficiently close to each other. It can be said that the method for calculating the pulse wave velocity hfPWV was sufficiently accurate. The unit of the pulse wave velocity hfPWV displayed in FIG. 9 is “m / sec”.

  Returning to FIG. 4, the pulse wave propagation information display control means 63 measures or calculates each pulse measured or calculated corresponding to a plurality of types of two sites in the subject as a measurement result of the pulse wave propagation information measuring device 20. Wave propagation information is displayed relatively on the same screen of the display unit 53. In other words, the pulse wave propagation information display control unit 63 relatively displays a plurality of types of pulse wave propagation speeds PWV calculated by the pulse wave propagation speed calculation unit 55 in the same screen of the display unit 53.

  The pulse wave propagation information display control means 63 preferably uses a pulse wave propagation speed PWV that 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 55. The pulse wave propagation speed PWV corresponding to any one of the aorta, the peripheral artery, and the peripheral arteriole is displayed relatively on the same screen of the display unit 53. For example, the pulse wave propagation speed hfPWV corresponding to the section from the aorta starting part to the thigh in the subject and / or the pulse wave propagation speed hbPWV corresponding to the section from the aorta starting part to the upper arm part correspond to the aorta. As pulse wave propagation information, the pulse wave propagation speed faPWV corresponding to the section from the thigh to the ankle is used as the pulse wave propagation information corresponding to the peripheral artery, and the pulse corresponding to the section from the ankle to the toe is used. The wave propagation velocity aTPWV is relatively displayed on the same screen of the display unit 53 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 with the subject's midline as the symmetry plane is displayed relatively on the same screen of the display unit 53.

  FIG. 10 is a view showing an example of a pulse wave velocity fraction displayed on the display 53 by the pulse wave propagation information display control means 63, 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 propagation velocity hcPWV corresponding to the section from the aortic origin in the subject to the carotid artery of the neck on the hC axis is shown from the aortic origin in the subject on the hF axis. The pulse wave propagation speed hfPWV corresponding to the section from the thigh to the femoral artery, the pulse wave propagation speed hbPWV corresponding to the section from the aortic origin in the subject to the upper arm (brachial artery) on the hB axis, and the fA axis , The pulse wave velocity faPWV corresponding to the section from the femoral artery of the thigh to the ankle in the subject is a pulse corresponding to the section from the ankle to the toe of the toe in the subject on the aT axis. The wave propagation velocity aTPWV is shown respectively. Further, in the right half circle, pulse wave propagation information measured corresponding to an artery in the right half of the subject whose midline is the symmetry plane, in the left half of the left half of the subject whose midline is the symmetry plane, The pulse wave propagation information measured corresponding to the artery is shown. In FIG. 10, the segment of the artery belonging to the large / medium artery system is displayed as a display area ARA01, and the segment of the artery belonging to the peripheral arterial system is displayed as a background display area ARA02 different from the display area ARA01. The arterial segment belonging to the arteriole system is displayed as a background display area ARA03 different from the display areas ARA01 and ARA02. Specifically, the axes hC, hF, and hB are separately displayed so as to belong to the large / medium artery system, the axis fA to the peripheral arterial system, and the axis aT to the peripheral arteriole system. Since the section from the aortic origin to the ankle spans the aorta / middle artery system and the peripheral artery system, the axis hA is displayed at the boundary between the display areas ARA01 and ARA02.

  FIG. 11 is a diagram showing another example of the pulse wave velocity fraction displayed on the display unit 53 by the pulse wave propagation information display control means 63. That is, the pulse wave propagation information display control unit 63 may perform the display of FIG. 11 instead of FIG. In the image shown in FIG. 11, in addition to the display of the display areas ARA01 to ARA03, an appropriate range (normal speed range) for each artery belonging to each type is shown in the pulse wave velocity fraction of FIG. 10 described above. It has become. In other words, the appropriate range for each artery is the range of the pulse wave velocity PWV corresponding to the normal value (health value) individually in each arterial system. In FIG. 11, an area ARA11 is an appropriate range for the large and middle arterial system, an area ARA12 is an appropriate range for the peripheral arterial system, and an area ARA13 is an appropriate range for the peripheral arteriole system. In the pulse wave velocity fraction shown in FIG. 11, the artery corresponding to any axis is within the appropriate range. For example, the pulse wave velocity PWV on the axis aB corresponding to the right half is shown. When the point is out of the area ARA11, the pulse wave velocity hbPWV corresponding to the section corresponding to the axis aB, that is, the section from the aortic origin to the upper arm belonging to the aorta / middle artery system deviates from the appropriate range. Is considered to be.

  FIG. 12 is a flowchart for explaining a main part of the pulse wave propagation information display control by the arithmetic and control unit 59, 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 at S1 is negative, the routine is terminated accordingly. If the determination at S1 is affirmative, the routine proceeds to S2.

  In S2, control is performed so that each cuff pressure of the cuff 22 wound around each measurement site of the subject becomes a predetermined pulse wave detection pressure. Next, in S3, the heart sound is detected by the heart sound microphone 48, and the electrocardiographic induction signal ECG corresponding to the heart sound for one beat is detected by the electrocardiogram electrode sensor 52, and the heart sound corresponds to the heart sound for the one beat. The pulse wave signal to be detected is detected by the pulse wave detector and pulse wave circuit (pressure pulse wave detector) 65 corresponding to each measurement site. Next, in S4, each cuff pressure such as the cuff 22 wound around each measurement site of the subject is discharged.

  Next, in S5 corresponding to the operation of the pulse wave velocity calculating means 55, the pulse wave velocity hcPWV, hbPWV, haPWV, aTPWV corresponding to each measurement site of the subject is calculated. At this time, the PEP correction process is performed when calculating the pulse wave propagation time PWT between the aortic root and the other part.

  Next, in S6 corresponding to the operation of the pulse wave velocity calculating means 55, the pulse wave velocity hfPWV corresponding to the section from the aortic root to the femoral artery of the thigh and the femoral artery of the thigh are calculated. A pulse wave propagation velocity faPWV corresponding to the section to the ankle is calculated.

  Next, in S7 corresponding to the operation of the pulse wave propagation information display control means 63, the pulse wave propagation speed component as shown in FIGS. 10 to 11 is displayed on the display 53 corresponding to the calculation results in S5 and S6. After the image is displayed, this routine is terminated. In the above control, S2 and S4 correspond to the operation of the cuff pressure control means 62.

  Thus, according to the present embodiment, the pulse wave propagation information measuring device 20 measures the pulse wave propagation information related to the pulse wave propagation velocity PWV between the two sites of the subject's artery. Specifically, the pulse wave propagation information measuring device 20 includes pulse wave propagation information corresponding to a section from the first site of the artery to a second site downstream of the first site, and Based on pulse wave propagation information corresponding to a section downstream from the first part and corresponding to a section from the artery between the first part and the second part to a third part on the branched artery, the first part Pulse wave propagation information corresponding to the section from the part to the fourth part located in the middle of the path of the artery between the first part and the second part, and the section from the fourth part to the second part Corresponding pulse wave propagation information is calculated. Therefore, the pulse wave propagation information corresponding to the measurement target section having the fourth part as one end can be obtained without directly detecting the pulse wave at the fourth part. For example, this is particularly useful when it is difficult to directly detect a pulse wave at the fourth region.

  Further, according to the present embodiment, specifically, the first part is an aortic root, the second part is an ankle part, the third part is an upper arm part, and the fourth part is a large part. The thigh. Therefore, when it is difficult to detect a pulse wave by detecting a pulse wave or the like at the aortic origin, upper arm, and ankle where it is easy to detect the pulse wave that is the basis for obtaining the pulse wave propagation information. It is possible to obtain pulse wave propagation information corresponding to a measurement target section having a large thigh as one end. Specifically, the pulse wave propagation speeds hfPWV and faPWV corresponding to the measurement target section can be obtained.

  Further, according to the present embodiment, the pulse wave propagation information specifically corresponding to the section from the first part to the second part is that from the first part (aortic origin) to the second part (ankle). Part) is the first pulse wave propagation time haPWT in which the pulse wave propagates to the first part, and the pulse wave propagation information corresponding to the section from the first part to the third part is the first part (aortic origin) Is the second pulse wave propagation time hbPWT in which the pulse wave propagates from to the third part (upper arm). Then, the pulse wave propagation information measuring device 20 determines the difference between the first pulse wave propagation time haPWT and the second pulse wave propagation time hbPWT (= haPWT−hbPWT) from the aortic origin to the thigh. The pulse wave velocity hfPWV corresponding to the section to the femoral artery of the head and the pulse wave velocity faPWV corresponding to the section from the femoral artery to the ankle of the thigh are calculated. Therefore, the pulse wave propagation speeds hfPWV and faPWV corresponding to the measurement target section having the fourth part as one end can be obtained without directly detecting the pulse wave at the fourth part (thigh).

  Further, according to the present embodiment, the pulse wave propagation information measuring device 20 calculates the pulse wave propagation time PWT between the subject's aortic root and another part when the electrocardiographic induction signal ECG or A provisional pulse wave propagation time PWT ′ is measured using a predetermined characteristic time point (for example, the Q time point or the R time point in FIG. 2) in the heart sound signal PCG as a measurement start point, and the measurement start point is used as the aortic valve opening time point Ps (see FIG. 5), the value obtained by correcting the provisional pulse wave propagation time PWT ′ based on the time difference between the predetermined characteristic time point and the aortic valve opening time point Ps (for example, the precursor time PEP), The pulse wave propagation time PWT between the aortic origin and other parts is used. In short, the PEP correction process is executed. Therefore, even when it is difficult to directly detect the aortic valve opening time Ps of the heart, it is possible to obtain the pulse wave propagation time PWT between the aortic origin and other parts with high accuracy.

  Further, according to the present embodiment, the pulse wave propagation information measuring device 20 is measured or calculated corresponding to two types of two parts including the pulse wave propagation speeds hcPWV, hbPWV, haPWV, aTPWV, hfPWV, and faPWV. The pulse wave propagation information is relatively displayed on the same screen of the display 53. Therefore, the pulse wave propagation information for each type of artery can be shown in an objectively viewable and relatively comparable 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, according to the present embodiment, the pulse wave propagation information measuring device 20 compares the pulse wave propagation information measured corresponding to the arteries in the left and right bodies with the midline of the subject as a symmetry plane within the same screen. Therefore, the pulse wave propagation information for each type of artery in each of the left and right bodies can be objectively displayed.

  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, 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 embodiment described above, the pulse wave velocity calculating means 55 calculates both the pulse wave velocity hfPWV and faPWV based on the pulse wave propagation times haPWT and hbPWT. It does not matter if only one of faPWV is calculated.

  In the above-described embodiment, in S6 of FIG. 12, the pulse wave velocity hfPWV corresponding to the section from the aortic root to the femoral artery of the thigh and the section from the femoral artery to the ankle of the thigh The pulse wave propagation speed faPWV corresponding to is calculated, but it is also conceivable that other pulse wave propagation information related to the pulse wave propagation speeds hfPWV and faPWV is calculated.

  In the above-described embodiment, the first part of the present invention corresponds to the aortic root, the second part corresponds to the ankle part, the third part corresponds to the upper arm part, and the fourth part. Corresponds to the thigh, but the correspondence between the first to fourth parts and each part of the subject need not be limited to this.

  In the above-described embodiment, the pulse wave velocity calculating means 55 performs the PEP correction process when calculating the pulse wave propagation time PWT between the aortic root of the subject and other parts. The pulse wave propagation time PWT may be calculated without performing the PEP correction process. For example, it is conceivable to set the pulse wave propagation speed PWV without correcting the provisional pulse wave propagation time PWT ′.

  Further, in the above-described embodiment, each pulse wave propagation velocity PWV is displayed as shown in FIG. 10 or FIG. 11, but it may be displayed in other modes.

  In the above-described embodiment, the pulse wave velocity measuring device 20 detects pulse waves in each of the neck, upper arm, ankle, and toe of the subject, and the pulse corresponding to the detection result. Wave propagation information was displayed, but the measurement site is at least better than this, for example, the pulse wave in each of the upper arm part and the ankle part of the subject is detected, and each of a plurality of types of arteries according to the detection result It is also possible to display pulse wave propagation information corresponding to.

  Further, in the above-described embodiment, the pulse wave velocity measuring device 20 includes the individual cuffs 22 and the like or the pulse wave detectors corresponding to the arteries in the left and right bodies having the midline of the subject as a symmetry plane. Although it was provided, it may be provided with only a device corresponding to the half body. In such an aspect, it is preferable that measurements corresponding to the arteries in the left and right bodies having the midline of the subject as a symmetry plane are individually performed at predetermined time intervals, and the measurement results are aggregated. It is displayed on the same screen on the display 53.

  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.

20: Pulse wave propagation information measuring device

Claims (5)

A pulse wave propagation information measuring device for measuring pulse wave propagation information which is a pulse wave propagation time or a pulse wave propagation speed between two parts of a living artery,
Pulse wave propagation information corresponding to a section from the first part of the artery to the second part downstream from the first part, and the first part and downstream from the first part to the first part Based on the pulse wave propagation information corresponding to the section from the artery between the second part to the third part on the artery branched from the first part, between the first part and the second part One or both of the pulse wave propagation information corresponding to the section from the fourth part to the second part and the pulse wave propagation information corresponding to the section from the fourth part to the second part are calculated. An apparatus for measuring pulse wave propagation information. The first part is an aorta starting part of the living body , the second part is an ankle part of the living body , the third part is an upper arm part of the living body , and the fourth part is a large part of the living body. It is a thigh part. The pulse wave propagation information measuring device according to claim 1 characterized by things. The pulse wave propagation information corresponding to the section from the first part to the second part is a first pulse wave propagation time in which the pulse wave propagates from the first part to the second part,
The pulse wave propagation information corresponding to the section from the first part to the third part is a second pulse wave propagation time in which the pulse wave propagates from the first part to the third part,
Based on the difference between the first pulse wave propagation time and the second pulse wave propagation time, the pulse wave propagation speed included in the pulse wave propagation information corresponding to the section from the first part to the fourth part; The pulse wave propagation according to claim 1 or 2, wherein one or both of the pulse wave propagation speed included in the pulse wave propagation information corresponding to the section from the fourth part to the second part is calculated. Information measuring device. When calculating the pulse wave propagation time between the aortic origin of the living body and another part, the provisional pulse wave propagation time with a predetermined characteristic time point in the electrocardiographic induction signal or heart sound signal as the measurement starting point A value obtained by correcting the provisional pulse wave propagation time based on the time difference between the predetermined characteristic time and the aortic valve opening time so that the measurement starting point can be regarded as the opening time of the aortic valve of the heart The pulse wave propagation information measuring device according to claim 3 , wherein the pulse wave propagation time between the aortic origin and another part is used. Including pulse wave propagation information calculated based on pulse wave propagation information corresponding to a section from the first part to the second part and pulse wave propagation information corresponding to a section from the first part to the third part 5. The pulse wave according to claim 1, wherein the pulse wave propagation information measured or calculated corresponding to a plurality of types of two parts is relatively displayed on the same screen. 6. Propagation information measuring device.

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