JP2014076226A - Pulse wave measuring apparatus - Google Patents

Abstract

A pulse wave measuring apparatus capable of accurately measuring a pulse wave is provided.
A pulse wave measuring device includes a chair-type device main body, an upper limb measuring unit, a lower limb measuring unit, a control unit, and a detecting unit. The detection unit 80 includes an upper limb movement amount detection unit 81, a lower limb movement amount detection unit 82, an upper limb inclination angle detection unit 83, and a lower limb inclination angle detection unit 84. The control unit 70 calculates the height position of the lower limb measurement unit 50 based on the detection value of the detection unit. The control unit 70 corrects the blood pressure measured by the upper limb measurement unit 40 and the lower limb measurement unit 50 based on the height position of the lower limb measurement unit 50.
[Selection] Figure 1

Description

  The present invention relates to a pulse wave measuring device.

  A conventional pulse wave measurement device has a measurement unit attached to an upper limb or a lower limb as a body limb (for example, Patent Document 1). The measurement unit measures the pulse wave of the attached limb.

JP 2003-230542 A

The pulse wave changes according to the difference between the height position of the measurement unit and the heart height position. The pulse wave measuring apparatus does not consider this point. For this reason, there is room for improvement in the accuracy of measurement results.
The present invention has been created based on the above background, and an object thereof is to provide a pulse wave measuring device capable of accurately measuring a pulse wave.

  This means is measured by the limb measurement unit that measures the pulse wave of at least one of the upper limb and the lower limb, the height position detection unit that detects the height position of the limb measurement unit, and the limb measurement unit. A pulse wave comprising: a controller that calculates pulse wave information as at least one of blood pressure and pulse wave velocity based on the pulse wave and corrects the pulse wave information based on a detection value of the height position detector Includes "measuring device".

  One form of the above-mentioned means is as follows: “The pulse wave measuring device has a chair-type device main body, the limb measurement unit is attached to the device main body, and has a height that changes a height position relative to the device main body. A pulse wave measuring device having a position changing function ”.

  One form of the above means is that “the pulse wave measuring device is a detection physics information detection unit that detects detection information related to the physique of the person being measured, and a physique information input unit for inputting input information relating to the physique of the person being measured And the control unit includes a pulse wave measurement device that changes a height position of the limb measurement unit according to at least one of the detection information and the input information.

  One form of the means is as follows: “The pulse wave measuring device has an angle detection unit, and the limb measurement unit is attached to an attachment portion of the device main body, and can change an inclination angle with respect to the attachment portion. The angle detection unit detects an inclination angle of the limb measurement unit, and the control unit corrects the pulse wave information using the inclination angle detected by the angle detection unit. Includes "measuring device".

  One form of the above-mentioned means is as follows: "The body limb measurement unit includes an upper limb measurement unit and a lower limb measurement unit, the upper limb measurement unit measures an upper limb pulse wave, and the lower limb measurement unit includes a lower limb pulse wave. And the control unit includes a pulse wave measuring device that calculates a ratio between the blood pressure of the upper limb and the blood pressure of the lower limb.

One form of the above means includes “the pulse wave measuring device includes a close contact device that closely contacts the limb measurement unit to the limb”.
One form of the means is as follows: “The apparatus main body includes a seat portion, a backrest portion, and an ottoman, and the backrest portion and the ottoman are inclined with respect to the seat portion, and the seat portion, the backrest portion, and The ottoman includes a pulse wave measuring device that can maintain the apparatus main body in a straight line by rotating the backrest and the ottoman relative to the seat.

  One form of the above-mentioned means is as follows: "The body limb measurement unit includes an upper limb measurement unit and a lower limb measurement unit, the upper limb measurement unit measures an upper limb pulse wave, and the lower limb measurement unit includes a lower limb pulse wave. The upper limb measurement unit maintains a state where a constant pressure is applied to the upper limb and measures a pulse wave of the upper limb, and the lower limb measurement unit maintains a state where a constant pressure is applied to the lower limb. The control unit includes a pulse wave measurement device that measures a pulse wave of a lower limb and calculates a pulse wave propagation velocity using the pulse wave of the upper limb and the pulse wave of the lower limb.

  One form of the above means is that “the pulse wave measuring device has a heart sound measuring unit for measuring a heart sound of the measurement subject, and the limb measuring unit maintains a state in which a certain pressure is applied to the upper limb and the lower limb. Then, the pulse wave of the upper limb and the pulse wave of the lower limb are measured, and the control unit calculates a pulse wave velocity using the heart sound measured by the heart sound measuring unit and the pulse wave measured by the limb measuring unit. "Pulse wave measuring device".

  One form of the above means is that “the pulse wave measuring device has an electrode for measuring an electrocardiogram of a measurement subject, and the control unit uses the electrocardiogram and the pulse wave measured by the limb measurement unit. "Pulse wave measuring device for calculating pulse wave velocity".

  One form of the above means includes “the pulse wave measuring device has a massage mechanism”.

  This pulse wave measuring apparatus can accurately measure a pulse wave.

It is a perspective view regarding the pulse wave measuring apparatus of 1st Embodiment, and is a perspective view which shows the whole structure of a pulse wave measuring apparatus. It is a side view regarding the pulse wave measuring apparatus of 1st Embodiment, and is a side view which shows the side structure of a backrest part tilting mechanism and an Ottoman tilting mechanism. It is a side view regarding the pulse wave measuring device of a 1st embodiment, and an operation figure showing a side structure when a backrest part tilting mechanism and an Ottoman tilting mechanism operate. It is a perspective view regarding the pulse wave measuring apparatus of 1st Embodiment, and is a perspective view which shows a state when a to-be-measured person sits on the pulse wave measuring apparatus. It is sectional drawing regarding the upper limb measurement part of 1st Embodiment, (a) is sectional drawing which shows the state which the cuff is contracting, (b) is sectional drawing which shows the state where the cuff is expanding. It is a schematic diagram regarding the pulse wave measuring device of the first embodiment, and schematically shows the height position when the upper limb measuring unit and the lower limb measuring unit are at the reference position. It is a schematic diagram regarding the pulse wave measurement device of the first embodiment, and is a schematic diagram schematically showing the height position when the upper limb measurement unit and the lower limb measurement unit slide. It is a schematic diagram regarding the pulse wave measurement device of the first embodiment, and is a schematic diagram schematically showing the height position when the inclination angles of the upper limb measurement unit and the lower limb measurement unit are changed. It is a graph regarding the pulse wave measuring apparatus of 1st Embodiment, and is a graph which shows a pressure fluctuation when measuring a blood pressure. It is a graph regarding the pulse wave measuring apparatus of 1st Embodiment, and is a graph which shows a pressure fluctuation when measuring a pulse wave propagation velocity. It is a graph regarding the pulse wave measuring apparatus of 1st Embodiment, and is a graph which shows an upper limb pulse wave velocity and a lower limb pulse wave velocity. It is a schematic diagram regarding the pulse wave measuring apparatus of 1st Embodiment, and is a schematic diagram which shows typically the blood vessel distance to a to-be-measured person's heart and limbs. It is a perspective view regarding the pulse wave measuring apparatus of 2nd Embodiment, and is a perspective view which shows the whole structure of a pulse wave measuring apparatus. It is a schematic diagram regarding the pulse wave measuring device of the second embodiment, and schematically shows the height position when the upper limb measuring unit and the lower limb measuring unit are at the reference position. It is a schematic diagram regarding the pulse wave measuring device of the second embodiment, and is a schematic diagram schematically showing the height position when the inclination angles of the upper limb measuring unit and the lower limb measuring unit are changed. It is a perspective view regarding the pulse wave measuring device of the 1st modification of a 1st embodiment, and is a perspective view showing the whole structure of a pulse wave measuring device. It is a perspective view regarding the pulse wave measuring apparatus of the 2nd modification of 1st Embodiment, and is a perspective view which shows the whole structure of a pulse wave measuring apparatus. It is the elements on larger scale regarding the pulse wave measuring device of the 3rd modification of a 1st embodiment, and is a front view showing a heart sound measuring part. It is a perspective view regarding the pulse wave measuring device of the 4th modification of a 1st embodiment, and is a perspective view showing the whole structure of a pulse wave measuring device. It is a perspective view regarding the pulse wave measuring device of the 5th modification of a 1st embodiment, and is a perspective view showing the whole structure of a pulse wave measuring device.

(First embodiment)
With reference to FIG. 1, the structure of the pulse wave measuring apparatus 1 is demonstrated.
The pulse wave measurement device 1 includes a chair-type device main body 10, an upper limb measurement unit 40, a lower limb measurement unit 50, a contact device 60, a control unit 70, a detection unit 80, an operation unit 91, and a display unit 92. The upper limb measurement unit 40 and the lower limb measurement unit 50 correspond to “body measurement unit”. The detection unit 80 corresponds to a “height position detection unit”. The operation unit 91 corresponds to a “physique information input unit”.

The apparatus main body 10 includes a backrest portion 11, a seat portion 13, an ottoman 14, an armrest 16, a backrest tilting mechanism 20 (see FIG. 2), and an ottoman tilting mechanism 30 (see FIG. 2).
Hereinafter, the direction from the side where the backrest 11 of the seat 13 is attached to the side where the ottoman 14 is attached is referred to as “rear Z2”. The direction from the side where the ottoman 14 of the seat 13 is attached to the side where the backrest 11 is attached is referred to as “rear Z2”. A direction including the front Z1 and the rear Z2 is referred to as a “depth direction Z”.

The backrest part 11 has rails 12 at both ends in the width direction of the backrest part 11. The rail 12 extends in the height direction of the backrest portion 11 (hereinafter “backrest height direction Y”).
The seat portion 13 has a seat portion fixing portion 13A (see FIG. 2). The seat fixing portion 13A protrudes downward from an intermediate portion in the depth direction of the seat surface.

  The ottoman 14 has lower limb placement portions 14A adjacent in the width direction. Each lower limb placement portion 14 </ b> A has a rail 15. The rail 15 extends in the height direction of the ottoman 14 (hereinafter, “ottoman height direction W”).

With reference to FIG. 2, the structure of the backrest tilting mechanism 20 and the ottoman tilting mechanism 30 will be described.
The backrest tilting mechanism 20 includes a motor 21, a rotating part 22, and an extendable part 23. The backrest tilting mechanism 20 is disposed inside the seat portion 13. The backrest tilting mechanism 20 changes the tilt angle of the backrest 11 with respect to the seat 13.

  The rotating part 22 attaches the backrest part 11 and the seat part 13. The elastic part 23 is connected to the lower end part of the backrest part 11 and the seat fixing part 13A. The motor 21 is attached to an intermediate part of the extendable part 23. When the motor 21 is driven, the expansion / contraction part 23 expands and contracts. When the telescopic part 23 contracts, the lower end part of the backrest part 11 is drawn into the front Z1, and the backrest part 11 rotates relative to the seat part 13 around the rotating part 22. For this reason, the upper end part of the backrest part 11 inclines toward back Z2.

  The ottoman tilting mechanism 30 includes a motor 31, a rotating unit 32, and a telescopic unit 33. The ottoman tilting mechanism 30 is disposed inside the seat portion 13. The ottoman tilting mechanism 30 changes the tilt angle of the ottoman 14 with respect to the seat 13.

  The rotating part 32 attaches the ottoman 14 and the seat part 13. The expansion / contraction part 33 is connected to the back and upper part of the ottoman 14 and the seat fixing part 13A. The motor 31 is attached to an intermediate part of the expansion / contraction part 33. When the motor 31 is driven, the expansion / contraction part 33 expands and contracts. When the telescopic part 33 extends, the ottoman 14 is pushed forward Z1 and the ottoman 14 rotates around the rotating part 32 relative to the seat part 13. For this reason, the lower end portion of the ottoman 14 is directed further forward Z1. The height positions of the rotating unit 22 and the rotating unit 32 are the same. Hereinafter, the height positions of the rotating unit 22 and the rotating unit 32 are referred to as “supporting height positions”.

  As shown in FIG. 3, when the backrest portion 11 and the ottoman 14 rotate most around the rotating portions 22 and 32, the seat surface of the seat portion 13, the surface of the backrest portion 11, and the back surface of the lower limb of the ottoman 14 are placed. The surface is straight. That is, the backrest height direction Y, the ottoman height direction W, and the depth direction Z coincide. At this time, the height position of the upper limb measurement unit 40 and the height position of the lower limb measurement unit 50 also coincide.

With reference to FIG. 1, the structure of the upper limb measurement part 40 and the lower limb measurement part 50 is demonstrated.
Each upper limb measurement unit 40 includes an upper limb guide unit 41, a cuff 42, and a pressure sensor 43. Each upper limb measurement unit 40 is attached to the backrest unit 11. For this reason, when the backrest 11 is tilted with respect to the seat 13, each upper limb measuring unit 40 is tilted with respect to the seat 13. In other words, each upper limb measurement unit 40 is attached to the seat 13 so as to be tiltable. The seat 13 for each upper limb measurement unit 40 corresponds to an “attachment unit”.

  Each upper limb guide part 41 has a C-shaped cross section. Each upper limb guide portion 41 is attached to the right rail 12 and the left rail 12 in the width direction of the backrest portion 11, respectively. Each upper limb guide part 41 moves in the backrest height direction Y along the rail 12 by driving a motor (not shown). The cuff 42 is disposed inside the upper limb guide portion 41. The cuff 42 is expanded by the air supplied from the contact device 60. The pressure sensor 43 detects the pressure applied to the cuff 42. The pressure sensor 43 is disposed in a tube 62 that connects the cuff 42 and the air pump 61 of the contact device 60. The pressure sensor 43 detects the pressure applied to the cuff 42 by detecting the pressure in the tube 62.

  Each lower limb measurement unit 50 includes a lower limb guide unit 51, a cuff 52, and a pressure sensor 53. Each lower limb measurement unit 50 is attached to the ottoman 14. For this reason, when the ottoman 14 is tilted with respect to the seat 13, each measuring unit 50 is tilted with respect to the seat 13. In other words, each lower limb measuring unit 50 is attached to the seat 13 so as to be tiltable. In addition, the seat part 13 with respect to each leg measurement part 50 is corresponded to an "attachment part."

  Each lower limb guide part 51 has a C-shaped cross section. Each lower limb guide portion 51 is attached to the right rail 15 and the left rail 15, respectively. Each lower limb guide portion 51 moves in the ottoman height direction W along the rail 15 by driving a motor (not shown). The cuff 52 is disposed inside the lower limb guide part 51. The cuff 52 is expanded by the air supplied from the contact device 60. The pressure sensor 53 detects the pressure applied to the cuff 52. The pressure sensor 53 is disposed in a tube 62 that connects the cuff 52 and the air pump 61 of the contact device 60. The pressure sensor 53 detects the pressure applied to the cuff 52 by detecting the pressure in the tube 62.

  The contact device 60 includes an air pump 61 and a tube 62. The close contact device 60 supplies air from the air pump 61 to the cuffs 42 and 52 via the tube 62 based on a command from the control unit 70.

The detection unit 80 includes an upper limb movement amount detection unit 81, a lower limb movement amount detection unit 82, an upper limb inclination angle detection unit 83, and a lower limb inclination angle detection unit 84.
The upper limb movement amount detection unit 81 detects the movement amount of the upper limb guide unit 41 with respect to the rail 12 (hereinafter, “upper limb movement amount ΔLA”). As the upper limb movement amount detection unit 81, for example, a linear encoder is employed.

  The lower limb movement amount detection unit 82 detects the movement amount of the lower limb guide unit 51 with respect to the rail 15 (hereinafter referred to as “lower limb movement amount ΔLL”). As the lower limb movement amount detection unit 82, for example, a linear encoder is employed.

  The upper limb inclination angle detector 83 detects the amount of change in the inclination angle of the backrest 11 relative to the seat 13 (hereinafter referred to as “angle change ΔθA”). As the upper limb inclination angle detector 83, for example, a rotary encoder is employed. The upper limb inclination angle θA is equal to the angle formed by the horizontal plane and the upper limb measurement unit 40.

  The lower limb inclination angle detector 84 detects the amount of change in the inclination angle of the ottoman 14 relative to the seat 13 (hereinafter, “angle change amount ΔθL”). As the lower limb inclination angle detection unit 84, for example, a rotary encoder is employed. Note that the lower limb inclination angle θL is equal to the angle formed between the vertical plane orthogonal to the horizontal plane and the lower limb measurement unit 50.

  The control unit 70 measures pulse wave information by the upper limb measurement unit 40 and the lower limb measurement unit 50 based on the operation of the operation unit 91 of the measurement subject. The control unit 70 calculates the height positions of the upper limb measurement unit 40 and the lower limb measurement unit 50 based on the detection value of the detection unit 80. The control unit 70 drives the backrest tilting mechanism 20 and the ottoman tilting mechanism 30 based on the operation of the operation unit 91 of the measurement subject. The operation unit 91 includes a button (not shown) for the person to be measured to control the power supply of the pulse wave measuring device 1 and a button (not shown) for inputting the height. The display unit 92 displays pulse wave information. The height corresponds to “input information”.

  With reference to FIG. 4 and FIG. 5, operation | movement of the upper limb measurement part 40 and the lower limb measurement part 50 at the time of the measurement of a pulse wave is demonstrated. 4 shows the operation of the upper limb measurement unit 40, the same applies to the lower limb measurement unit 50.

As shown in FIG. 4, the upper limb measurement unit 40 is located at the upper limb reference position when the power is off. The lower limb measurement unit 50 is located at the lower limb reference position when the power is off.
When measuring the pulse wave information, the control unit 70 moves the upper limb guide unit 41 and the lower limb guide unit 51 along the rails 12 and 15 based on the height of the measurement subject. When the pulse wave is measured, the height position of the upper limb measurement unit 40 matches the height position of the heart 103 of the measurement subject estimated from the height. The height position of the upper limb measurement unit 40 corresponds to the height position of the central portion 40C in the backrest height direction Y of the cuff 42. The height position of the lower limb measurement unit 50 corresponds to the height position of the central portion 50C of the cuff 52 in the ottoman height direction W.

  As shown in FIG. 5, the contact device 60 (see FIG. 1) supplies air to the cuffs 42 and 52 and compresses the upper limb 101 or the lower limb 102. The control unit 70 (see FIG. 1) controls the supply of air to the cuffs 42 and 52 and gradually contracts the cuffs 42 and 52 to lower the pressure. The pressure sensors 43 and 53 sense pressure fluctuations when the cuffs 42 and 52 shown in FIG. 9 are contracted. The control unit 70 calculates the blood pressure of the upper limb (hereinafter referred to as “upper limb blood pressure PA”) and the blood pressure of the lower limb (hereinafter referred to as “lower limb blood pressure PL”) using the pressure fluctuation detected by the pressure sensors 43 and 53 and an algorithm. .

A method for calculating the height positions of the upper limb measurement unit 40 and the lower limb measurement unit 50 will be described with reference to FIGS.
As shown in FIG. 6, when the upper limb measurement unit 40 is at the upper limb reference position, the upper limb measurement unit 40 is positioned higher than the support height position by the reference upper limb height HA (cm).

  Further, when the upper limb measuring unit 40 is at the upper limb reference position, the position with respect to the rail 12 is positioned at the upper limb reference slide position, and a reference upper limb inclination angle with respect to the seat portion 13 (hereinafter, “reference upper limb inclination angle θAX”). Lean on. When in the upper limb reference slide position, the distance from the rotating unit 22 to the upper limb measurement unit 40 is referred to as “upper limb reference distance LA”.

When the lower limb measurement unit 50 is at the lower limb reference position, the lower limb measurement unit 50 is positioned at a position lower than the support height position by the reference lower limb height HL (cm).
When the lower limb measurement unit 50 is at the lower limb reference position, the position with respect to the rail 15 is positioned at the lower limb reference slide position, and tilts with respect to the seat 13 at a reference lower limb inclination angle (hereinafter referred to as “lower limb inclination angle θLX”). When in the lower limb reference slide position, the distance from the rotation unit 32 to the lower limb measurement unit 50 is defined as “lower limb reference distance LL”.

With reference to FIG. 7, changes in the height positions of the upper limb measurement unit 40 and the lower limb measurement unit 50 when the upper limb measurement unit 40 and the lower limb measurement unit 50 move with respect to the rails 12 and 15 will be described.
The upper limb measurement unit 40 moves relative to the rail 12 by the upper limb movement amount ΔLA. The control unit 70 calculates a change amount of the height position (hereinafter, “upper limb height change amount ΔAX”) based on the upper limb movement amount ΔLA and the reference upper limb inclination angle θAX. The control unit 70 calculates the difference in height between the height position of the upper limb measurement unit 40 and the support height position (hereinafter, “upper limb height HAX”) based on the reference upper limb height HA and the upper limb height change amount ΔAX. To do. Specifically, the control unit 70 calculates the upper limb height HAX by the following formulas (1) and (2).

ΔAX = ΔLA × sin θAX (1)
HAX = HA + ΔAX (2)

The lower limb measurement unit 50 moves relative to the rail 15 by the lower limb movement amount ΔLL. The control unit 70 calculates the amount of change in height position (hereinafter referred to as “lower limb height change amount ΔLX”) based on the lower limb movement amount ΔLL and the reference lower limb inclination angle θLX. The control unit 70 calculates the difference in height between the height position of the lower limb measurement unit 50 and the support height position (hereinafter, “lower limb height HLX”) based on the reference lower limb height HL and the upper limb height change ΔLX. To do. Specifically, the control unit 70 calculates the lower limb height HLX by the following formulas (3) and (4).

ΔLX = ΔLL × cos θLX (3)
HLX = HL + ΔLX (4)

With reference to FIG. 8, the change in the height position of the upper limb measurement unit 40 and the lower limb measurement unit 50 when the inclination of the backrest 11 and the ottoman 14 with respect to the seat 13 is changed will be described.

  The upper limb measurement unit 40 rotates from the reference upper limb inclination angle θAX by an inclination angle change amount ΔθAX. The control unit 70 calculates a final upper limb inclination angle (hereinafter, “upper limb inclination angle θA”) based on the reference upper limb inclination angle θAX and the inclination angle change amount ΔθAX. Specifically, the control unit 70 calculates the upper limb inclination angle θA by the following equation (5).

θA = θAX + ΔθAX (5)

Based on the upper limb reference distance LA and the upper limb movement amount ΔLA, the control unit 70 calculates a distance from the rotating unit 22 to the upper limb measurement unit 40 (hereinafter, “upper limb measurement distance LAX”). Specifically, the control unit 70 calculates the upper limb measurement distance LAX by the following equation (6).

LAX = LA + ΔLA (6)

The control unit 70 calculates the upper limb height HAY based on the upper limb inclination angle θA and the upper limb measurement distance LAX. Specifically, the control unit 70 calculates the upper limb height HAY by the following equation (7).

HAY = LAX × sin θA (7)

The lower limb measurement unit 50 rotates from the reference lower limb inclination angle θLX by the inclination angle change amount ΔθLX. The control unit 70 calculates a final lower limb inclination angle (hereinafter, “lower limb inclination angle θL”) based on the reference lower limb inclination angle θLX and the inclination angle change amount ΔθLX. Specifically, the control unit 70 calculates the lower limb inclination angle θL by the following equation (8).

θL = θLX + ΔθLX (8)

The control unit 70 calculates a distance from the rotation unit 22 to the lower limb measurement unit 50 (hereinafter, “lower limb measurement distance LLX”) based on the lower limb reference distance LL and the lower limb movement amount ΔLL. Specifically, the control unit 70 calculates the lower limb measurement distance LLX by the following equation (9).

LLX = LL + ΔLL (9)

The control unit 70 calculates the lower limb height HLY based on the lower limb inclination angle θL and the lower limb measurement distance LLX. Specifically, the control unit 70 calculates the lower limb height HLY by the following equation (10).

HLY = LLX × cos θL (10)

The control unit 70 calculates a difference from the height of the heart 103 to the height of the lower limb (hereinafter, “lower limb height HX”) based on the upper limb height HAY and the lower limb height HLY. Specifically, the control unit 70 calculates the lower limb height HX by the following equation (11).

HX = HAY + HLY (11)

Here, the blood pressure measured by the upper limb measurement unit 40 and the lower limb measurement unit 50 is affected by the hydrostatic pressure. When the height position at the time of measurement of the upper limb measurement unit 40 and the lower limb measurement unit 50 is higher than the height position of the heart 103, the blood pressure is lower than the blood pressure measured at the height position of the heart 103. Specifically, when the height position at the time of measurement of the upper limb measurement unit 40 and the lower limb measurement unit 50 is 10 cm higher than the height position of the heart 103, the blood pressure is about 7 mmHg than the blood pressure measured at the height position of the heart 103. Low.

  Further, when the height position at the time of measurement by the upper limb measurement unit 40 and the lower limb measurement unit 50 is lower than the height position of the heart 103, the blood pressure becomes higher than the blood pressure measured at the height position of the heart 103. Specifically, when the height position at the time of measurement of the upper limb measurement unit 40 and the lower limb measurement unit 50 is 10 cm lower than the height position of the heart 103, the blood pressure is about 7 mmHg than the blood pressure measured at the height position of the heart 103. high.

  The control unit 70 matches the height position of the upper limb measurement unit 40 with the height position of the heart 103 when measuring the pulse wave. On the other hand, the height position of the lower limb measurement unit 50 is lower than the height position of the heart 103 when measurement is performed while the measurement subject is sitting on the apparatus main body 10. For this reason, the lower limb blood pressure PL is higher than the accurate lower limb blood pressure. Therefore, the control unit 70 corrects the lower limb blood pressure PL based on the lower limb height HX. Specifically, the control unit 70 calculates the final lower limb blood pressure PLX by the following equation (12).

PLX = PL-HX × 7/10 (12)

With reference to FIG. 4 and FIGS. 10-12, the calculation method of a pulse wave velocity is demonstrated.

The control unit 70 (see FIG. 1) calculates the pulse wave propagation velocity using the measurement values of the upper limb measurement unit 40 and the lower limb measurement unit 50.
As shown in FIG. 4, the contact device 60 supplies air to the cuffs 42 and 52 to compress the upper limb 101 or the lower limb 102 with a constant pressure for a predetermined time. The pressure sensors 43 and 53 sense pressure fluctuations. The controller 70 calculates the pulse wave velocity using the pressure fluctuations detected by the pressure sensors 43 and 53 (see FIG. 10) and the algorithm.

  FIG. 11 shows values detected by the pressure sensor 43 of the upper limb measurement unit 40 and pulse wave fluctuations detected by the pressure sensor 53 of the lower limb measurement unit 50. FIG. 11 corresponds to a part of the pressure fluctuation shown in FIG.

  The timing T1 at which the detection value of the pressure sensor 43 starts to rise is earlier than the timing T2 at which the detection value of the pressure sensor 53 starts to rise by the time difference (hereinafter, “time difference TX”). As shown in FIG. 12, the time difference TX results from the difference between the blood vessel distance DA from the heart 103 to the upper limb measurement unit 40 and the blood vessel distance DL from the heart 103 to the lower limb measurement unit 50.

  The control unit 70 calculates a pulse wave velocity (hereinafter, “pulse wave velocity PWV”) based on the height input by the operation unit 91 and a preset database. Specifically, the control unit 70 calculates the pulse wave velocity PWV by the following equation (13).

PWV = (DL-DA) / TX (13)

The control unit 70 displays the value of the lower limb blood pressure PLX relative to the upper limb blood pressure PA and the pulse wave propagation velocity PWV on the display unit 92. The value of lower limb blood pressure PLX relative to upper limb blood pressure PA is used as an index for diagnosing stenosis and occlusion of the lower limb due to arteriosclerosis. The pulse wave velocity PWV is used as an index for diagnosing blood vessel hardness. For this reason, the person to be measured can easily grasp the state of his / her blood vessel by confirming the display on the display unit 92. The value of the lower limb blood pressure PLX relative to the upper limb blood pressure PA corresponds to the “ratio of the upper limb blood pressure and the lower limb blood pressure”.

The pulse wave measuring device 1 of the present embodiment has the following effects.
(1) The pulse wave measurement device 1 calculates the lower limb height HX based on the detection value of the detection unit 80, and corrects the lower limb blood pressure PLX. For this reason, leg blood pressure PLX can be measured accurately.

  (2) The pulse wave measuring device 1 corrects the lower limb blood pressure PLX based on the lower limb height HX. For this reason, the posture of the measurement subject is not limited to the supine posture. For this reason, it is possible to perform measurement with an easy posture.

  (3) The pulse wave measuring device 1 is attached to the seat 13 so that the height positions of the upper limb measuring unit 40 and the lower limb measuring unit 50 can be changed. For this reason, it can suppress that the measurement position in a to-be-measured person's body shift | deviates mutually in the some to-be-measured person from which a physique differs.

  (3) The pulse wave measurement device 1 moves the positions of the upper limb measurement unit 40 and the lower limb measurement unit 50 according to the height. For this reason, the usability of the person to be measured is improved. Moreover, it can suppress that the measurement position in a to-be-measured person's body shift | deviates for every measurement compared with the case where a to-be-measured person moves the position of the upper limb measurement part 40 and the lower limb measurement part 50 himself.

  (4) The pulse wave measuring device 1 corrects the lower limb blood pressure PLX using the inclination angle detected by the inclination angle detectors 83 and 84. For this reason, the lower limb height HX can be calculated more accurately. Moreover, since the backrest 11 and the ottoman 14 incline with respect to the seat part 13, the to-be-measured person can measure a pulse wave measuring apparatus 1 with a comfortable posture.

(5) The pulse wave measuring device 1 calculates the ratio between the upper limb blood pressure and the lower limb blood pressure. For this reason, the person to be measured can easily grasp the state of his / her blood vessel.
(6) The pulse wave measuring device 1 has a contact device 60. For this reason, compared with the structure which winds a cuff manually, a to-be-measured person's usability improves. Further, the control unit 70 supplies air to the cuffs 42 and 52 in accordance with the physique of the measurement subject. For this reason, the convenience of the measurement subject is further improved.

  (7) The pulse wave measuring device 1 can maintain the device body 10 in a straight line. For this reason, it is possible to measure the pulse wave in a state where the measurement subject is sleeping. For this reason, it is easy to compare the measurement result of the pulse wave by the pulse wave measurement device 1 with the measurement result of the pulse wave measurement in the state where the measurement subject is lying down.

  (8) The pulse wave measurement device 1 calculates the pulse wave propagation velocity PWV using the pulse waves measured by the upper limb measurement unit 40 and the lower limb measurement unit 50. For this reason, the person to be measured can easily grasp the state of his / her blood vessel, for example, the hardness of the blood vessel wall.

(Second Embodiment)
The pulse wave measuring device 1 of the present embodiment has a different configuration in the following part compared to the pulse wave measuring device 1 of the first embodiment, and has the same configuration in other parts. That is, the upper limb measurement unit 40 is attached to the armrest 16.

As shown in FIG. 13, the armrest 16 has a rail 17 on the upper surface. The upper limb guide portion 41 of the upper limb measurement unit 40 is attached to the rail 17.
As shown in FIG. 15, the armrest 16 is rotatably attached to the seat portion 13 around the rotating portion 18 at the end on the rear Z2 side.

A method for calculating the height position of the upper limb measurement unit 40 will be described with reference to FIGS. 14 and 15.
As shown in FIG. 14, when the power is off, the upper limb measurement unit 40 is located at the upper limb reference position. The height position of the upper limb measurement unit 40 corresponds to the height position of the central portion 40D in the direction along the rail 17 of the cuff 42 (hereinafter, “armrest height direction V”).

The control unit 70 estimates the height position of the heart 103 based on the height.
The upper limb measurement unit 40 is located at a position lower than the height position of the heart 103 when in the upper limb reference position. The control unit 70 calculates a difference between the estimated height position of the heart 103 and the height position of the upper limb measurement unit 40 (hereinafter, “reference upper limb height HR (cm)”. When the arm is at the upper limb reference position, the position relative to the rail 12 is positioned at the upper limb reference slide position, and the upper limb reference slide is inclined with respect to the seat 13 at a reference upper limb inclination angle θR (hereinafter referred to as “reference upper limb inclination angle θRX”). When it is in the position, the distance from the rotation unit 22 to the upper limb measurement unit 40 is referred to as “upper limb reference distance LR”.

With reference to FIG. 15, the change of the height position of the upper limb measurement part 40 when the inclination with respect to the seat part 13 of the armrest 16 is changed is demonstrated.
The upper limb measurement unit 40 rotates from the reference upper limb inclination angle θRX by an inclination angle change amount ΔθRX. The control unit 70 calculates the upper limb inclination angle θR based on the reference upper limb inclination angle θRX and the inclination angle change amount ΔθRX. Specifically, the control unit 70 calculates the upper limb inclination angle θR by the following equation (21).

θR = θRX + ΔθRX (21)

The control unit 70 calculates the distance from the rotation unit 22 to the upper limb measurement unit 40 (hereinafter, “upper limb measurement distance LRX”) based on the upper limb reference distance LR and the upper limb movement amount ΔLR. Specifically, the control unit 70 calculates the upper limb measurement distance LRX by the following equation (22).

LRX = LR + ΔLR (22)

The control unit 70 calculates the upper limb height HRY based on the upper limb inclination angle θR and the upper limb measurement distance LRX. Specifically, the control unit 70 calculates the upper limb height HRY by the following equation (23).

HRY = LRX × sin θR (23)

The height position of the lower limb measurement unit 50 is lower than the height position of the heart 103. For this reason, the upper limb blood pressure PR is higher than the accurate lower limb blood pressure. Therefore, the control unit 70 corrects the upper limb blood pressure PR based on the upper limb height HRY. Specifically, the control unit 70 calculates the final upper limb blood pressure PRX by the following equation (24).

PRX = PR−HRY × 7/10 (24)

The pulse wave measuring device 1 of the present embodiment has the effects (1) to (8) of the first embodiment and the following effects.

  (9) In the pulse wave measuring device 1, the armrest 16 rotates with respect to the seat portion 13. For this reason, the person to be measured can perform measurement with a more comfortable posture as compared with the configuration in which the armrest 16 does not rotate with respect to the seat portion 13.

(Other embodiments)
The pulse wave measuring device 1 includes embodiments other than the first embodiment and the second embodiment. Hereinafter, the modification as other embodiment of this pulse wave measuring device 1 is shown. The following modifications can be combined with each other.

  The pulse wave measurement device 1 of the first embodiment calculates the height position and the upper limb inclination angle of the upper limb measurement unit 40 with reference to the central portion 40C in the backrest height direction Y of the cuff 42. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 according to the modified example calculates the height position and the inclination angle of the upper limb measuring unit 40 with reference to the upper end or the lower end of the central portion 40C in the backrest height direction Y of the cuff 42. In short, the height position of the upper limb measurement unit 40 and the position used as the reference for the tilt angle can be changed to any position of the cuff 42.

  The pulse wave measurement device 1 according to the second embodiment calculates the height position and the inclination angle of the upper limb measurement unit 40 using the central portion 40D of the cuff 42 in the armrest height direction V as a reference. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring apparatus 1 according to the modified example calculates the height position and the inclination angle of the upper limb measuring unit 40 with reference to the upper end or the lower end of the cuff 42 in the armrest height direction V. In short, the height position of the upper limb measurement unit 40 and the position used as the reference for the tilt angle can be changed to any position of the cuff 42.

-Upper limb measurement part 40 of 2nd Embodiment measures the pulse wave of a wrist. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the modified upper limb measurement unit 40 measures the pulse wave of the finger.
The pulse wave measurement device 1 of each embodiment calculates the height position and the inclination angle of the lower limb measurement unit 50 with reference to the central portion 50C of the cuff 52 in the ottoman height direction W. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 of the modified example calculates the height position and the inclination angle of the lower limb measuring unit 50 with reference to the upper end or the lower end of the central portion 50C of the cuff 52 in the ottoman height direction W. In short, the height position of the lower limb measurement unit 50 and the position used as the reference for the tilt angle can be changed to any position of the cuff 52.

  In the pulse wave measurement device 1 of each embodiment, each lower limb measurement unit 50 slides with respect to the ottoman 14. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, in the pulse wave measurement device 1 of the modification shown in FIG. 16, each lower limb measurement unit 50 is fixed to the ottoman 114. The ottoman 114 slides with respect to the seat portion 13.

  -Pulse wave measuring device 1 of each embodiment measures pulse wave information based on a measured value of upper limb measuring part 40 and lower limb measuring part 50. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 of the modification shown in FIG. 17 includes a heart sound measuring unit 75 and a microphone support unit 76. The heart sound measuring unit 75 has a microphone for measuring heart sounds. The microphone support portion 76 can be bent. The person to be measured measures the heart sound by bending the microphone support portion 76 to place the heart sound measuring portion 75 at a position close to the heart 103. The control unit 70 calculates the pulse wave velocity PWV based on the second sound of the heart sound measured by the heart sound measuring unit 75 and the measured values of the upper limb measuring unit 40 and the lower limb measuring unit 50. For this reason, it is possible to obtain information regarding the hardness of the blood vessel between the heart 103 and the upper limb 101 and the blood vessel wall between the heart 103 and the lower limb 102. For this reason, the diagnosis which specified the site | part more can be performed.

  A further modification of the modification shown in FIG. 17 is shown in FIG. In the pulse wave measurement device 1 shown in FIG. 18, a chest portion 77 is attached to the heart sound measurement unit 75. The chest holding part 77 is larger than the heart sound measuring part 75. Moreover, it has a shape along the surface shape of the chest of the measurement subject. For this reason, the person being measured can easily place the heart sound measuring unit 75 in the breast contacting unit 77.

  -Pulse wave measuring device 1 of each embodiment measures pulse wave information based on a measured value of upper limb measuring part 40 and lower limb measuring part 50. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 according to the modification shown in FIG. 19 includes a wrist electrode 78 and an ankle electrode 79. The control unit 70 measures an electrocardiogram based on detection values of the wrist electrode 78 and the ankle electrode 79. The controller 70 accurately measures the second sound of the heart sound from the electrocardiogram. For this reason, the pulse wave velocity PWV can be calculated more accurately. The heart sounds are noisy. For this reason, the pulse wave measuring apparatus 1 that includes the heart sound measuring unit 75 and measures heart sounds may be provided with an algorithm for determining the second sound of the heart sound in association with the electrocardiogram by measuring the electrocardiogram.

  -The pulse wave measuring apparatus 1 of each embodiment can also be provided with the massage mechanism 200 as shown in FIG. This pulse wave measuring device 1 can further relax the user by the massage of the massage mechanism 200. In addition, massage that improves blood flow and blood vessel function can be performed.

  The cuffs 42 and 52 of the pulse wave measuring device 1 of each embodiment can be used as a massage mechanism that massages the upper limb and the lower limb. Specifically, air is supplied to the cuffs 42 and 52 by the contact device 60, and the upper and lower limbs are massaged by pressurization.

  -Pulse wave measuring device 1 of each embodiment has adhesion device 60. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the close contact device 60 is omitted in the pulse wave measurement device 1 of the modified example. In this case, the person to be measured supplies air to the cuffs 42 and 52 with a manual pump.

  In the upper limb measurement unit 40 of each embodiment, the cuff 42 is disposed inside the upper limb guide unit 41. However, the configuration of the upper limb measurement unit 40 is not limited to this. For example, the upper limb guide part 41 can be omitted. In this case, the person to be measured wraps the cuff 42 around the upper limb himself.

  In the lower limb measurement unit 50 of each embodiment, the cuff 52 is disposed inside the lower limb guide unit 51. However, the configuration of the lower limb measurement unit 50 is not limited to this. For example, the lower limb guide part 51 can be omitted. In this case, the person to be measured wraps the cuff 52 around the upper limb himself.

  In the pulse wave measurement device 1 of each embodiment, the control unit 70 moves the upper limb measurement unit 40 and the lower limb measurement unit 50 on the rails 12 and 15 based on the height of the measurement subject. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, in the pulse wave measuring apparatus 1 of the modified example, the measurement subject moves the upper limb measurement unit 40 and the lower limb measurement unit 50 on the rails 12 and 15 according to the positions of the measurement subject's upper limb and lower limb.

  -Pulse wave measuring device 1 of each embodiment has operation part 91 for inputting a height. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 according to the modification includes a detection physique information detection unit for detecting the height or the positions of the upper limbs and the lower limbs. The control unit 70 moves the upper limb measurement unit 40 and the lower limb measurement unit 50 based on the detection information of the detection physique information detection unit.

  -The pulse wave measuring device 1 of each embodiment calculates a height position based on the movement amount and rotation amount of the upper limb measurement unit 40 and the lower limb measurement unit 50. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the upper limb measurement unit 40 and the lower limb measurement unit 50 of the modified example have height sensors. The height sensor detects the height from the horizontal plane. In this case, the pulse wave measuring device 1 can also use the device main body 10 as a bed. The pulse wave measuring device 1 can also omit the device body 10.

  -The pressure sensors 43 and 53 of each embodiment are arrange | positioned at the tube 62. FIG. However, the configuration of the pressure sensors 43 and 53 is not limited to this. For example, the pressure sensors 43 and 53 of the modified example are arranged inside the cuffs 42 and 52. In short, the pressure sensors 43 and 53 can be arranged at any position as long as the pressure fluctuation of the cuffs 42 and 52 can be detected.

  In the backrest tilting mechanism 20 of each embodiment, the tilt angle of the backrest 11 changes due to the expansion / contraction of the expansion / contraction part 23 of each embodiment. However, the configuration of the backrest tilting mechanism 20 is not limited to this. For example, the backrest tilting mechanism 20 in which the rotating portion 22 is directly rotated by the rotation of the motor can be used. In short, any backrest tilting mechanism can be adopted as long as the tilting mechanism can change the tilting angle of the backrest 11 with respect to the seat 13.

  In the ottoman tilting mechanism 30 of each embodiment, the tilt angle of the ottoman 14 changes due to the expansion / contraction of the expansion / contraction part 33 of each embodiment. However, the configuration of the ottoman tilting mechanism 30 is not limited to this. For example, the ottoman tilting mechanism 30 in which the rotating unit 32 is directly rotated by the rotation of the motor can be used. In short, any ottoman tilting mechanism can be adopted as long as the ottoman tilting mechanism can change the tilt angle of the ottoman 14 with respect to the seat portion 13.

  The pulse wave measuring device 1 of each embodiment has a display unit 92. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring device 1 of the modified example omits the display unit 92. In this case, the pulse wave measuring device 1 has an information output unit for outputting the calculation result to another storage device.

  The pulse wave measurement device 1 of the first embodiment corrects the lower limb blood pressure PL based on the detection value of the detection unit 80, and the pulse wave measurement device 1 of the second embodiment corrects the upper limb blood pressure PR and the lower limb blood pressure PL. To do. However, the pulse wave measuring device 1 is not limited to this. For example, the modified pulse wave measuring device 1 corrects the pulse wave propagation speed based on the detection value of the detection unit 80.

  In the pulse wave measurement device 1 of each embodiment, the detection unit 80 detects the movement amount and the rotation amount of the measurement units 40 and 50. However, the configuration of the pulse wave measuring device 1 is not limited to this. For example, the pulse wave measuring apparatus 1 according to the modification detects the movement amount and the rotation amount based on a command value from the control unit 70 to the motor.

  DESCRIPTION OF SYMBOLS 1 ... Pulse wave measuring device, 10 ... Apparatus main body, 11 ... Backrest part, 13 ... Seat part (attachment part), 14 ... Ottoman, 16 ... Armrest, 40 ... Upper limb measurement part (limb measurement part), 50 ... Lower limb measurement Part (body measurement part), 60 ... contact device, 70 ... control part, 75 ... heart sound measurement part, 78 ... wrist electrode, 79 ... ankle electrode, 80 ... detection part (height position detection part), 81 ... upper limb movement An amount detection unit, 82 ... a lower limb movement amount detection unit, 83 ... an upper limb inclination angle detection unit, 84 ... a lower limb inclination angle detection unit, 91 ... an operation unit (physique information input unit), 200 ... a massage mechanism.

Claims (11)

A limb measurement unit that measures the pulse wave of at least one of the upper limb and the lower limb;
A height position detection unit for detecting a height position of the limb measurement unit;
Calculate pulse wave information as at least one of blood pressure and pulse wave velocity based on the pulse wave measured by the limb measurement unit, and correct the pulse wave information based on the detection value of the height position detection unit A pulse wave measuring device comprising: The pulse wave measuring device has a chair-type device body,
The pulse wave measurement device according to claim 1, wherein the limb measurement unit is attached to the device main body and has a height position changing function of changing a height position with respect to the device main body. The pulse wave measuring device has at least one of a detection physique information detection unit that detects detection information related to the physique of the measured person, and a physique information input unit for inputting input information related to the physique of the measured person,
The pulse wave measurement device according to claim 2, wherein the control unit changes a height position of the limb measurement unit according to at least one of the detection information and the input information. The pulse wave measuring device has an angle detection unit,
The limb measurement unit is attached to an attachment part of the apparatus main body, and has a tilt function capable of changing an inclination angle with respect to the attachment part,
The angle detection unit detects an inclination angle of the limb measurement unit,
The pulse wave measurement device according to claim 2, wherein the control unit corrects the pulse wave information using the tilt angle detected by the angle detection unit. The limb measurement unit has an upper limb measurement unit and a lower limb measurement unit,
The upper limb measurement unit measures the pulse wave of the upper limb,
The lower limb measurement unit measures the pulse wave of the lower limb,
The pulse wave measuring device according to any one of claims 1 to 4, wherein the control unit calculates a ratio between the blood pressure of the upper limb and the blood pressure of the lower limb. The pulse wave measurement device according to any one of claims 1 to 5, wherein the pulse wave measurement device includes a close contact device that causes the limb measurement unit to be in close contact with the limb. The device main body has a seat, a backrest, and an ottoman,
The backrest and the ottoman are inclined with respect to the seat;
The seat portion, the backrest portion, and the ottoman can maintain the apparatus main body in a straight line by rotating the backrest portion and the ottoman with respect to the seat portion. The pulse wave measuring device according to any one of claims 3 to 6. The limb measurement unit has an upper limb measurement unit and a lower limb measurement unit,
The upper limb measurement unit measures the pulse wave of the upper limb,
The lower limb measurement unit measures the pulse wave of the lower limb,
The upper limb measurement unit measures the pulse wave of the upper limb while maintaining a state where a certain pressure is applied to the upper limb,
The lower limb measuring unit measures the pulse wave of the lower limbs while maintaining a state where a certain pressure is applied to the lower limbs,
The pulse wave measurement device according to any one of claims 1 to 7, wherein the control unit calculates a pulse wave velocity using a pulse wave of an upper limb and a pulse wave of a lower limb. The pulse wave measuring device has a heart sound measuring unit that measures a heart sound of the measurement subject,
The limb measurement unit measures the pulse wave of the upper limb and the pulse wave of the lower limb while maintaining a state where a certain pressure is applied to the upper limb and the lower limb,
The pulse according to any one of claims 1 to 8, wherein the control unit calculates a pulse wave velocity using a heart sound measured by the heart sound measurement unit and a pulse wave measured by the limb measurement unit. Wave measuring device. The pulse wave measuring device has an electrode for measuring an electrocardiogram of a measurement subject,
The pulse wave measurement device according to any one of claims 1 to 9, wherein the control unit calculates a pulse wave velocity using the electrocardiogram and the pulse wave measured by the limb measurement unit. The pulse wave measurement device according to claim 1, wherein the pulse wave measurement device includes a massage mechanism.