JP2015043882A - Blood pressure manometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blood pressure manometer capable of displaying information related to the constriction of a blood vessel, etc.SOLUTION: A blood pressure manometer (1) includes first blood pressure measuring means (23, 27 and 29) and second blood pressure measuring means (25, 27 and 29) for measuring the blood pressure in a part of a living body, and display means (7 and 9) for displaying a difference D between a first blood pressure value which is the measurement result by the first blood pressure measuring means, and a second blood pressure value which is the measurement result by the second blood pressure measuring means, or a value calculated based on the difference D. The first blood pressure measuring means and the second blood pressure measuring means can be equipped, for example, with pulse wave measuring means (23 and 25) for measuring a pulse wave in the part, and blood pressure estimation means (29) for estimating blood pressure based on the pulse wave, respectively.

Description

  The present invention relates to a sphygmomanometer.

  Conventionally, various blood pressure monitors have been proposed (see Patent Documents 1 and 2). The sphygmomanometer described in Patent Document 1 detects a pulse wave from cuffs attached to the left and right outer ears, and determines the blood pressure from the detected pulse wave. In addition, the sphygmomanometer described in Patent Document 2 includes a plurality of cuffs that are worn on the extremities and measure blood pressure.

JP 2006-212178 A JP 2006-280809 A

  Conventional blood pressure monitors cannot display information related to blood vessel stenosis or the like even though the blood pressure measurement value itself can be displayed. This invention is made | formed in view of the above point, and it aims at providing the blood pressure meter which can solve the subject mentioned above.

  The sphygmomanometer of the present invention includes a first blood pressure measurement unit and a second blood pressure measurement unit that measure blood pressure in a part of a living body, a first blood pressure value that is a measurement result of the first blood pressure measurement unit, Display means for displaying a difference D from a second blood pressure value, which is a measurement result of the second blood pressure measuring means, or a value calculated based on the difference D.

  The blood pressure monitor of the present invention can display the difference D or a value calculated based on the difference D. A user of a sphygmomanometer (for example, a doctor) uses the difference D or a value calculated based on the difference D to determine a problem of the patient's blood vessel (for example, the blood vessel on the side of the patient's body that has a lower blood pressure. Stenosis, aortic detachment, aortitis syndrome, etc.) can be diagnosed.

  Each of the first blood pressure measuring unit and the second blood pressure measuring unit includes, for example, a pulse wave measuring unit that measures a pulse wave in the part and a blood pressure estimating unit that estimates a blood pressure based on the pulse wave. be able to. In this case, blood pressure can be measured more easily.

  The sphygmomanometer of the present invention includes, for example, a third blood pressure measurement unit that measures blood pressure using a cuff, a third blood pressure value that is a measurement result of the third blood pressure measurement unit, and the first blood pressure value. Alternatively, calibration means for calibrating the first blood pressure value or the second blood pressure value can be provided based on the difference from the second blood pressure value. In this case, blood pressure can be measured more accurately.

  The sphygmomanometer of the present invention can include, for example, a display changing unit that inverts the display of the display unit in the vertical direction and maintains the positional relationship in the horizontal direction of items displayed on the display unit. . In this case, the display content of the display means can be displayed in an easy-to-understand manner for those on both sides of the sphygmomanometer.

  The display means can display, for example, the difference D or a history of values calculated based on the difference D. In this case, the tendency of temporal change such as the difference D can be more easily understood.

2 is a block diagram showing a configuration of a sphygmomanometer 1. FIG. 1 is a perspective view illustrating a configuration of a sphygmomanometer 1. It is explanatory drawing showing the structure of 23 for pulse-wave detection probes left hand. It is a flowchart showing the process which the blood pressure meter 1 performs. 11 is an explanatory diagram illustrating a display example on the display unit 9. FIG. 11 is an explanatory diagram illustrating a display example on the display unit 9. FIG. It is explanatory drawing showing the change of the display in a 1st display change process, Comprising: 7A represents the display mode before a change, 7B represents the display mode after a change. It is explanatory drawing showing a log | history display aspect.

An embodiment of the present invention will be described with reference to the drawings.
1. Configuration of Sphygmomanometer 1 The configuration of the sphygmomanometer 1 will be described with reference to FIGS. As shown in FIG. 1, a sphygmomanometer 1 includes a blood pressure measurement unit 3 using a pulse wave, a blood pressure measurement unit 5 using a cuff, a control unit 7, a display unit 9, an input unit 11, a right probe switch 13, a left probe switch 15, and a right A calibration button 17, a left calibration button 19, a cuff use / non-use button 21, and a display change switch 22 are provided.

  The blood pressure measurement unit 3 using a pulse wave measures blood pressure (systolic blood pressure and diastolic blood pressure) based on the pulse wave at the finger of the right hand and the finger of the left hand of the patient, respectively. The blood pressure measurement unit 3 using a pulse wave includes a pulse wave detection probe left hand 23, a pulse wave detection probe right hand 25, a pulse wave signal acquisition unit 27, and a blood pressure estimation unit 29.

  The pulse wave detection probe left hand 23 detects a pulse wave at the fingertip (one embodiment of a part of the living body) of the patient's left hand. The pulse wave detection probe right hand 25 detects a pulse wave at the fingertip (one embodiment of a part of the living body) of the right hand of the same patient. The detailed configurations of the pulse wave detection probe left hand 23 and the pulse wave detection probe right hand 25 will be described later.

  The pulse wave signal acquisition unit 27 acquires a pulse wave signal detected by the pulse wave detection probe left hand 23 and the pulse wave detection probe right hand 25 and outputs the pulse wave signal to the blood pressure estimation unit 29. The blood pressure estimation unit 29 estimates the blood pressure of the patient's left hand based on the pulse wave acquired by the pulse wave detection probe left hand 23. Further, the blood pressure estimation unit 29 estimates the blood pressure of the right hand of the same patient based on the pulse wave acquired by the pulse wave detection probe right hand 25.

  As a method of estimating the blood pressure of the left hand and the blood pressure of the right hand based on the pulse wave, a known method can be used as appropriate, for example, a method described in Japanese Patent No. 5218136 can be used. This method is as follows. First, the relationship between the feature amount of the biological information obtained from the pulse wave signal and the blood pressure is obtained in advance by pre-learning for each predetermined blood pressure (for example, every 1 mmHg in the range of 80 to 160 mmHg). When estimating blood pressure, binarization discrimination is performed for each of a plurality of different predetermined blood pressures with respect to the characteristic amount of the biological information obtained by measurement (whether the blood pressure corresponding to the characteristic amount is less than or equal to the predetermined blood pressure). )I do. Then, based on the determination result of the binarization determination, a binary number sequence in which the binarization determination results for each blood pressure are arranged is created, and this binary number sequence and the number sequence for each blood pressure in the code table prepared in advance To estimate blood pressure.

  Here, as the feature amount of the biological information obtained from the pulse wave signal, a velocity pulse wave, an acceleration pulse wave, a volume AI, or the like can be used. Moreover, the discrimination function for binarizing the blood pressure can be generated by, for example, Adaboost. Further, as another method for estimating the blood pressure of the left hand and the blood pressure of the right hand based on the pulse wave, for example, a method described in Japanese Patent Application Laid-Open No. 2009-89828 may be used.

  The cuff blood pressure measurement unit 5 has a well-known configuration capable of measuring blood pressure using a cuff. The cuff 31 can be attached to the right or left hand of a patient, the pressure sensor 33 for measuring the pressure in the cuff 31, and the cuff 31. A pressure control unit 35 that controls the pressure and a blood pressure measurement unit 37 are provided.

  The cuff 31, the pressure sensor 33, and the pressure control unit 35 are connected to each other by an air tube 39 and can circulate air. The blood pressure measurement unit 37 measures blood pressure based on the outputs of the pressure sensor 33 and the pressure control unit 35.

  The control unit 7 is a well-known computer including a CPU, a ROM, a RAM, and the like (all not shown), and executes processing to be described later. As shown in FIG. 2, the display unit 9 is a liquid crystal display provided in a part of the housing 41 of the sphygmomanometer 1 and can display various images.

  The input unit 11 obtains input results from the right probe switch 13, the left probe switch 15, the right calibration button 17, the left calibration button 19, the cuff use / non-use button 21, and the display change switch 22, and inputs these input results. Output to the control unit 7.

  The right probe switch 13 executes measurement by the pulse wave detection probe right hand 25 when it is ON, and stops measurement by the pulse wave detection probe right hand 25 when it is OFF. Further, the left probe switch 15 causes the pulse wave detection probe left hand 23 to perform measurement when it is ON, and stops the measurement using the pulse wave detection probe left hand 23 when it is OFF. The configurations of the right probe switch 13 and the left probe switch 15 will be described later together with the configuration of the pulse wave detection probe left hand 23.

  Each of the right calibration button 17 and the left calibration button 19 is a push button type switch provided on the upper surface of the housing 41 as shown in FIG. When the right calibration button 17 is pressed, the calibration value storage relating to the blood pressure of the right hand is executed. In addition, when the left calibration button 19 is pressed, calibration value storage, which will be described later, relating to the blood pressure of the left hand is executed.

  As shown in FIG. 2, the cuff use / non-use button 21 is a switch provided on the upper surface of the housing 41, and is a switch that can slide the knob 21A in the horizontal direction. The knob 21A can be slid to one of the “use cuff” side and the “do not use cuff” side. When the knob 21A is on the “use cuff” side, when the blood pressure measurement unit 3 using the pulse wave is used to measure the blood pressure of the right hand and the blood pressure of the left hand, the measurement using the blood pressure measurement unit 5 using the cuff is automatically performed. Executed.

  On the other hand, when the knob 21A is on the “not using cuff” side, even if the blood pressure measurement unit 3 using the pulse wave is used to measure the blood pressure of the right hand and the blood pressure of the left hand, the measurement using the blood pressure measurement unit 5 using the cuff is performed. Is not executed.

The display change switch 22 is a switch for instructing change of the display mode in the display unit 9. Details of the display mode change will be described later.
Next, the configurations of the pulse wave detection probe left hand 23 and the pulse wave detection probe right hand 25 will be described with reference to FIGS. As shown in FIG. 2, the pulse wave detection probe left hand 23 and the pulse wave detection probe right hand 25 are provided on the upper surface of the housing 41 of the sphygmomanometer 1. The position of the pulse wave detection probe left hand 23 is a position on the left side of the housing 41, and is a suitable position for placing the finger 101A of the left hand 101 of the patient. The position of the pulse wave detection probe right hand 25 is a position on the right side of the housing 41, and is a suitable position for placing the finger 103A of the right hand 103 of the same patient.

As shown in FIG. 3, the pulse wave detection probe left hand 23 includes a lens 43, a light emitting unit 45, a light receiving unit 47, a substrate 49, and a lens support 51.
The lens 43 is provided at the center of the upper surface 51A of the lens support 51 and can transmit light in the vertical direction. The light emitting unit 45 and the light receiving unit 47 are located below the lens 43 and are provided on the substrate 49. The light emitting unit 45 is formed of a light emitting diode, and irradiates green light (light including a wavelength of 5000 to 8000 mm) upward through the lens 43. This light is reflected in the capillaries of the patient's finger placed on the lens 43. The reflected light passes through the lens 43 and is received by the light receiving unit 47. The light receiving unit 47 is a photodiode, and outputs an electric signal (pulse wave signal) when the light is received.

  The lens support 51 has a substantially box-like basic form with an open bottom, and has a flange portion 51 </ b> B projecting outward near the lower end thereof. Of the lens support 51, a portion other than the flange portion 51 </ b> B is fitted into a rectangular opening 53 provided in the housing 41, and the flange 51 </ b> B is below the housing 41 around the opening 53. Lurking in. The light emitting unit 45, the light receiving unit 47, and the substrate 49 are accommodated inside the lens support 51 and are fixed so that their positions with respect to the lens support 51 are constant.

  A spring 54 is provided between the bottom surface of the flange portion 51 </ b> B and a support body 55 described later, and urges the lens support body 51 upward. Therefore, when the lens support 51 and the lens 43 are not pressed by the patient's finger, the lens support 51 is pushed upward until the flange portion 51B contacts the back surface of the housing 41. On the other hand, when the lens support 51 and the lens 43 are pressed downward with the patient's finger, the spring 54 is contracted and the lens support 51 moves downward.

  A left probe switch 15 is provided below the pulse wave detection probe left hand 23. The left probe switch 15 includes a support body 55, a fixed terminal 57, a movable terminal 59, and a pressing piece 61. The support body 55 supports the fixed terminal 57 and the movable terminal 59 on the upper surface thereof. The movable terminal 59 is movable, and can move to a position where it comes into contact with the fixed terminal 57 as well as a non-contact position. When the fixed terminal 57 and the movable terminal 59 are in contact, the left probe switch 15 is ON, and when both are not in contact, the left probe switch 15 is OFF.

  The pressing piece 61 is a member that protrudes downward from the lower surface of the substrate 49. Therefore, the pressing piece 61 moves up and down with the vertical movement of the substrate 49 (that is, the vertical movement of the lens support 51). When the position of the lens support 51 is on the upper side, the pressing piece 61 is also on the upper side, the movable terminal 59 is not pushed down, and the fixed terminal 57 and the movable terminal 59 are not in contact with each other (the left probe switch 15 is turned off). Become).

  On the other hand, when the lens support 51 is pushed down by the patient's finger, the position of the pressing piece 61 is also lowered, and the pressing piece 61 presses the movable terminal 59 in the direction of the fixed terminal 57 to bring them into contact with each other. Becomes ON.

  Therefore, when the patient does not push down the lens support 51 and the lens 43 with the finger, the left probe switch 15 is turned OFF. On the other hand, when the patient pushes down the lens support 51 and the lens 43 with the finger, the left probe switch 15 is turned off. Becomes ON.

  The pulse wave detection probe right hand 25 has the same configuration as the pulse wave detection probe left hand 23. A left probe switch 15 having a configuration similar to that of the right probe switch 13 is located below the pulse wave detection probe right hand 25 and operates in the same manner as the right probe switch 13.

  The pulse wave detection probe left hand 23, the pulse wave signal acquisition unit 27, and the blood pressure estimation unit 29 are an embodiment of the first blood pressure measurement unit, and the pulse wave detection probe right hand 25, the pulse wave signal acquisition unit 27, The blood pressure estimation unit 29 is an embodiment of the second blood pressure measurement unit, the control unit 7 and the display unit 9 are an embodiment of the display unit, and the pulse wave detection probe for the left hand 23 and the pulse wave detection probe The right hand 25 is an embodiment of the pulse wave measurement means, the blood pressure estimation section 29 is an embodiment of the blood pressure estimation means, and the cuff blood pressure measurement section 5 is an embodiment of the third blood pressure measurement means. The control unit 7 is an embodiment of the calibration unit and the display change unit.

2. Blood pressure measurement process executed by the sphygmomanometer 1 The blood pressure measurement process executed by the sphygmomanometer 1 (particularly the control unit 7) will be described with reference to FIGS. 2 and 4 to 6. In this process, as shown in FIG. 2, the patient places the finger 103A of the right hand 103 on the pulse wave detection probe right hand 25, pushes the lens support 51, turns on the right probe switch 13, Also, it is executed when the finger 101A of the left hand 101 is placed on the pulse wave detection probe left hand 23, the lens support 51 is pushed in, and the left probe switch 15 is turned on.

  In step 1 of FIG. 4, it is determined whether or not the cuff use / non-use button 21 is in the “not use cuff” state. If it is in the state of “not using cuff”, the process proceeds to step 2, and if it is in the state of “using cuff”, the process proceeds to step 7.

In step 2, the blood pressure measurement unit 3 using a pulse wave is used to measure the blood pressure of the right hand and the blood pressure of the left hand.
In step 3, it is determined whether there is a calibration value stored in the control unit 7. If there is a stored calibration value, the process proceeds to step 4. If there is no stored calibration value, the process proceeds to step 5. The calibration value refers to the measured value in the blood pressure measuring unit 3 by the pulse wave for the same part (for example, the right hand or the left hand) of the same patient, and the measured value in the blood pressure measuring unit 5 by the cuff is A2. Is a value represented by (A1-A2). The calibration value includes a calibration value for the right hand and a calibration value for the left hand. The calibration value is stored in step 14 described later.

  In step 4, the right hand blood pressure and the left hand blood pressure measured in step 2 are calibrated. Specifically, the calibration value for the right hand is subtracted from the blood pressure of the right hand measured in step 2 above. The value after subtraction is the blood pressure of the right hand after calibration. Further, the calibration value for the left hand is subtracted from the blood pressure of the left hand measured in Step 2 above. The value after subtraction is the blood pressure of the left hand after calibration.

  In step 5, the blood pressure measurement result is displayed on the display unit 9. The measurement results are the right blood pressure after calibration and the blood pressure of the left hand after calibration when an affirmative determination is made in step 3, and the measurement is performed in step 2 when a negative determination is made in step 3. The blood pressure of the right hand and the blood pressure of the left hand. The display unit 9 also displays a difference D obtained by subtracting the blood pressure of the left hand from the blood pressure of the right hand.

A display example of the display unit 9 is shown in FIG. In FIG. 5, the “right hand” column represents the blood pressure of the right hand, the “left hand” column represents the blood pressure of the left hand, and the “difference (right-left)” column represents the difference D.
In step 6, the blood pressure measured in step 2 and the value calibrated in step 3 (when step 3 is executed) are stored.

  On the other hand, if it is determined in step 1 that the state is “use cuff”, the process proceeds to step 7, and similarly to step 2, the blood pressure measurement unit 3 using the pulse wave is used to measure the blood pressure of the right hand and the left hand. Measure blood pressure.

In step 8, the blood pressure of the portion (right hand or left hand) to which the cuff is attached in the patient's body is measured using the cuff blood pressure measurement unit 5.
In step 9, as in step 3, it is determined whether there is a stored calibration value. If there is a stored calibration value, the process proceeds to step 10, and if there is no stored calibration value, the process proceeds to step 11.

  In Step 10, as in Step 4, the right hand blood pressure and the left hand blood pressure measured in Step 7 are calibrated. Specifically, the right hand calibration value is subtracted from the right hand blood pressure measured in step 7 to obtain the right hand blood pressure after calibration. Further, the left hand blood pressure measured in step 7 is subtracted from the left hand blood pressure to obtain the left hand blood pressure after calibration.

  In step 11, the blood pressure measurement result is displayed on the display unit 9. If the determination result in step 9 is affirmative, the measurement results are the blood pressure of the right hand after calibration and the blood pressure of the left hand after calibration. If the determination result is negative in step 9, the measurement result is measured in step 7. The blood pressure of the right hand and the blood pressure of the left hand. The display unit 9 also displays a difference D obtained by subtracting the blood pressure of the left hand from the blood pressure of the right hand. Further, the blood pressure measured using the cuff blood pressure measuring unit 5 in step 8 is also displayed on the display unit 9.

  A display example of the display unit 9 is shown in FIG. In FIG. 6, the “right hand” column represents the blood pressure of the right hand, the “left hand” column represents the blood pressure of the left hand, the “difference (right-left)” column represents the difference D, and the “cuff” column represents The blood pressure measured using the cuff blood pressure measuring unit 5 is represented.

In step 12, the blood pressure measured in steps 7 and 8 and the value calibrated in step 10 (when step 10 is executed) are stored.
In step 13, it is determined whether one of the right calibration button 17 and the left calibration button 19 is pressed. If either is pressed, the process proceeds to step 14, and if neither is pressed, the process is terminated.

  In step 14, when the right calibration button 17 is pressed, the measurement value of the blood pressure measurement unit 5 by the cuff is subtracted from the blood pressure of the right hand (or the blood pressure of the right hand after calibration if step 10 is executed), and the value is calculated. Is the calibration value for the right hand. Then, the calibration value for the right hand is stored in the control unit 7.

  In addition, when the left calibration button 19 is pressed, the measurement value in the blood pressure measurement unit 5 by the cuff is subtracted from the blood pressure of the left hand (the blood pressure of the left hand after calibration when step 10 is executed), and the value is subtracted. This is the calibration value for the left hand. Then, the calibration value for the left hand is stored in the control unit 7.

If both the right calibration button 17 and the left calibration button 19 are pressed, both the right-hand calibration value and the left-hand calibration value are calculated and stored in the control unit 7.
When the cuff is attached to the right hand of the patient, the user preferably presses the right calibration button 17 and does not press the left calibration button 19. Further, when the cuff is attached to the left hand of the patient, the user preferably presses the left calibration button 19 and does not press the right calibration button 17. This is because it is not preferable to calculate the calibration value using the measured value in the blood pressure measurement unit 5 by the cuff measured with the hand opposite to the hand that detected the pulse wave.

3. First display change process executed by sphygmomanometer 1 A first display change process executed by sphygmomanometer 1 will be described with reference to FIG. The first display change process is an operation corresponding to the first display change process on the display change switch 22 in a state where the measurement result as shown in FIG. This is executed when the first operation is performed.

  When the first operation is performed, the display mode of the display unit 9 is changed from the display mode shown in FIG. 7A (hereinafter referred to as the display mode before change) to the display mode shown in FIG. 7B (hereinafter referred to as the display mode after change). ).

  The display mode after the change is inverted in the vertical direction compared to the display mode before the change. However, the positional relationship of the items displayed on the display unit 9 in the left-right direction is the same in the display mode after the change and the display mode before the change (the positional relationship is maintained).

  That is, in both the display mode after the change and the display mode before the change, the “difference (right-left)” column is seen from the front side of the sphygmomanometer 1 (the lower side in FIGS. 5 and 6). On the rightmost side, the “right hand” column is the second from the right, the “left hand” column is the third from the right, and the “cuff” column is the leftmost.

In addition, when the first operation is performed again in the state where the display mode after the change is displayed on the display unit 9, the display mode of the display unit 9 returns to the display mode before the change.
Note that the first display change process can be executed even when the display unit 9 displays the measurement result in the state of “not using cuff” as shown in FIG.

4). Second display change process executed by sphygmomanometer 1 A second display change process executed by sphygmomanometer 1 will be described with reference to FIG. In the second display change process, an operation corresponding to the second display change process (hereinafter referred to as a second operation) is performed on the display change switch 22 in a state where the measurement result is displayed on the display unit 9. It is executed when done.

  When the second operation is performed, the display mode of the display unit 9 is changed to the display mode shown in FIG. 8 (hereinafter referred to as a history display mode). This history display mode is a graph that displays the history of the difference D, where the horizontal axis of the graph is the time axis and the vertical axis is the axis of the difference D. The past difference D is stored in Steps 6 and 12 above.

When the second operation is performed again in a state where the history display mode is displayed on the display unit 9, the display mode of the display unit 9 returns to the initial display mode.
5. Effect produced by sphygmomanometer 1 (1) The sphygmomanometer 1 can display a difference D obtained by subtracting the blood pressure of the left hand from the blood pressure of the right hand. Based on this difference D, the user (for example, a doctor) of the sphygmomanometer 1 has problems with the blood vessels of the patient (for example, stenosis of blood vessels on the lower blood pressure side of the patient's body, aortic detachment, aortitis syndrome, etc. ) Can be diagnosed.
(2) The sphygmomanometer 1 can create a calibration value based on the measurement value of the cuff blood pressure measurement unit 5 and calibrate the blood pressure of the right hand and the blood pressure of the left hand using the calibration value. As a result, blood pressure can be measured more accurately.
(3) The sphygmomanometer 1 measures the blood pressure based on the pulse wave using the blood pressure measurement unit 3 based on the pulse wave. Therefore, blood pressure can be easily measured.
(4) The sphygmomanometer 1 can execute the first display change process to invert the display mode on the display unit 9 in the vertical direction. As a result, the display content of the display unit 9 can be easily shown to the person on the other side of the sphygmomanometer 1 (the upper side in FIGS. 5 and 6).

Moreover, the positional relationship in the left-right direction of items displayed on the display unit 9 is the same even after the first display change process is executed. For example, in FIGS. 7A and 7B, the position of the “difference (right-left)” column in the left-right direction is on the same side as before the execution even after the execution of the first display change process. Therefore, even when the first display change process is executed, it is easy to grasp the items displayed on the display unit 9.
(5) The sphygmomanometer 1 can execute the second display change process and display the history of the difference D. Therefore, the tendency of the difference D over time can be understood more easily.
(6) The sphygmomanometer 1 can measure blood pressure simply by placing a finger, which is a measurement site, on the left hand 23 for the pulse wave detection probe and the right hand 25 for the pulse wave detection probe and pressing the finger. Therefore, blood pressure can be measured more easily.
(7) The user can easily select one of the measurement using the blood pressure measurement unit 5 by cuff and the measurement not using by operating the cuff use / non-use button 21.

6). Other Embodiments (1) The pulse wave detection probe for the left hand 23 and the pulse wave detection probe for the right hand 25 may be a probe wound around a patient's wrist, ankle, ear, or the like, or the wrist, ankle, ear A clip-type probe that sandwiches the like may be used.

  (2) The sphygmomanometer 1 may include a user selection button for selecting a user who uses the sphygmomanometer 1. In this case, the calibration value stored in step 14 is stored in association with the user name selected by the user selection button. When the calibration is performed in the steps 4 and 10, the calibration value associated with the user name selected by the user selection button is read and used.

  (3) Among the contents displayed on the display unit 9, those that satisfy a predetermined condition may be highlighted (for example, negative display or blinking display). Examples of the predetermined condition include a condition that the blood pressure, the difference D, and the like are out of a predetermined normal range.

  (4) Even if there is no operation with respect to the display change switch 22, the sphygmomanometer 1 changes the display mode of the display unit 9 between the display mode before the change and the display mode after the change every time a predetermined time elapses. Thus, it may be switched alternately.

(5) The sphygmomanometer 1 may not include the cuff blood pressure measurement unit 5 and the cuff use / non-use button 21. In this case, the structure of the sphygmomanometer 1 can be further simplified.
(6) The sphygmomanometer 1 may calculate a value calculated based on the difference D instead of or in addition to the difference D and display it on the display unit 9. Examples of the value calculated based on the difference D include the absolute value of the difference D, the ratio of the difference D to the blood pressure value, and the like.

  (7) The difference D may be a value obtained by subtracting the blood pressure of the right hand from the blood pressure of the left hand.

DESCRIPTION OF SYMBOLS 1 ... Blood pressure monitor, 3 ... Blood pressure measuring part by pulse wave, 5 ... Blood pressure measuring part by cuff, 7 ... Control part, 9 ... Display part, 11 ... Input part, 13 ... Right probe switch, 15 ... Left probe switch, 17 ... right calibration button, 19 ... left calibration button, 21 ... cuff use / non-use button, 21A ... knob, 22 ... display change switch, 23 ... pulse wave detection probe for left hand, 25 ... pulse wave detection probe for right hand, 27 ... Pulse wave signal acquisition unit, 29 ... Blood pressure estimation unit, 31 ... Cuff, 33 ... Pressure sensor, 35 ... Pressure control unit, 37 ... Blood pressure measurement unit, 39 ... Air tube, 41 ... Housing, 43 ... Lens, 45 ... Light emission , 47 ... light receiving part, 49 ... substrate, 51 ... lens support, 51A ... upper surface, 51B ... flange, 53 ... opening, 54 ... spring, 55 ... support, 57 ... fixed terminal, 59 ... movable terminal, 61 ... Pressing piece

Claims (5)

First blood pressure measuring means and second blood pressure measuring means for measuring blood pressure in a part of the living body;
The difference D between the first blood pressure value, which is the measurement result of the first blood pressure measurement means, and the second blood pressure value, which is the measurement result of the second blood pressure measurement means, or a value calculated based on the difference D Display means for displaying
A sphygmomanometer, comprising:   Each of the first blood pressure measuring means and the second blood pressure measuring means includes a pulse wave measuring means for measuring a pulse wave in the part, and a blood pressure estimating means for estimating a blood pressure based on the pulse wave. The sphygmomanometer according to claim 1. Third blood pressure measuring means for measuring blood pressure using a cuff;
The first blood pressure value or the second blood pressure is based on the difference between the third blood pressure value, which is the measurement result of the third blood pressure measuring means, and the first blood pressure value or the second blood pressure value. Calibration means for calibrating the value;
The sphygmomanometer according to claim 2, comprising:   4. The display device according to claim 1, further comprising: a display changing unit that inverts the display of the display unit in the vertical direction and maintains the positional relationship of the items displayed on the display unit in the horizontal direction. The sphygmomanometer according to claim 1.   The sphygmomanometer according to claim 1, wherein the display unit displays the difference D or a history of values calculated based on the difference D.

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