JP4412660B2 - Blood pressure monitor, blood pressure correction method, and measurement start pressure correction method - Google Patents

Description

  The present invention relates to a sphygmomanometer that corrects a blood pressure value according to a change in the posture of a subject, a blood pressure correction method when measuring a blood pressure value with an outer ear, and a measurement start pressure correction method.

  With the aging of society, dealing with adult lifestyle-related diseases has become a major social issue. It has been recognized that long-term blood pressure collection is very important, especially for diseases associated with high blood pressure. From this point of view, various biological information measuring devices including blood pressure values have been developed.

  As a biological information measuring device that can continuously measure blood pressure values without interfering with daily life, there is a patient monitoring device that is inserted into the external auditory canal or other part in the external ear and is always worn (for example, a patent) Reference 1). This apparatus calculates a pulse, a pulse wave, an electrocardiogram, a body temperature, an arterial blood oxygen saturation, a blood pressure value, and the like from received light amounts of infrared light and visible light scattered into the subject. However, this apparatus does not specify a specific means for measuring the blood pressure value.

  On the other hand, regarding the measurement of blood pressure values, blood pressure measurement devices based on pulsation waveforms of blood vessels are aligned with blood pressure measurement devices based on other methods such as the cuff vibration method and volume compensation method (for example, see Non-Patent Document 1). It is recognized as a powerful blood pressure measurement method.

The names of the auricles are based on Non-Patent Documents 2, 3, and 4. A high position indicates that the potential energy is high in the direction of gravitational acceleration, and a low position indicates that the energy is low.
Japanese Patent Laid-Open No. 9-128203 Kenichi Yamakoshi, Tatsuo Togawa: “Biological Sensors and Measurement Devices”, MM Japan Society / ME Textbook Series A-1, pages 39-52 Sobotta Illustrated Human Anatomy Volume 1 (Translation by Michio Okamoto), p. 126, Medical School, issued October 1, 1996 Sobotta Illustrated Human Anatomy Volume 1 (Translation by Michio Okamoto), p. 127, Medical School, issued October 1, 1996 Body map book (supervised and commentary by Nagao Takahashi), p. 20, Kodansha Co., Ltd., issued on January 29, 2004

  As described above, the specific method of continuous blood pressure measurement is not specified. The blood pressure value measured at the outer ear is affected by the hydrostatic pressure difference due to the difference in height between the outer ear and the heart. Since the subject lives daily and blood pressure values are expected to be measured in various postures, it is difficult to set this hydrostatic pressure difference in advance. Thus, it has been difficult to continuously measure accurate blood pressure values in the outer ear. Further, when the blood pressure value is measured by the outer ear, the pulse wave is detected from the peripheral blood vessel, and thus the measured blood pressure value is influenced by the inner diameter of the artery.

  In view of the above, an object of the present invention is to solve the above problems and to correct a blood pressure value measured at the outer ear to a blood pressure value measured at the height of the heart.

  In the present invention, it is preferable that a part of the subject is the outer ear and / or the periphery thereof. Furthermore, part of the subject is preferably the ear canal and / or pinna. Furthermore, it is preferable that a part of the subject is the tragus and / or its periphery. Hereinafter, a case where a part of the subject is the outer ear will be described as a representative.

  The present invention measures the blood pressure value at the height of the heart according to the detected posture of the subject by measuring the blood pressure value at the outer ear and simultaneously detecting the posture of the subject. It is characterized by correcting to a value. The posture detection particularly detects the height between the heart and the outer ear. By detecting the height between the heart and the outer ear, it is possible to correct the fluctuation of the blood pressure value due to the hydrostatic pressure difference caused by the height difference between the heart and the outer ear.

  Further, the present invention is characterized in that the pressure of pressing the outer ear when measuring the blood pressure value is detected by detecting the posture of the subject. By detecting the posture of the subject, the blood pressure value of the outer ear is predicted, and the measurement start pressure value at which pressurization or decompression is started is changed to a pressure at which the predicted blood pressure value can be measured. In this way, by predicting the pressure necessary for measuring the blood pressure value, it is not necessary to apply an extra pressure to the outer ear, so that the blood pressure value can be measured efficiently.

  Specifically, the sphygmomanometer according to the present invention includes a blood pressure measuring unit that measures a blood pressure value by compressing a part of an artery of the subject, a posture detecting unit that detects the posture of the subject, and the blood pressure measuring unit. Blood pressure correction means for calculating a corrected blood pressure value by correcting the measured blood pressure value based on the posture detected by the posture detection means.

  The corrected blood pressure value is a blood pressure value corrected according to the detected posture. By correcting blood pressure values measured at the outer ear to blood pressure values measured at the height of the heart according to the posture detected at the same time as the measurement of blood pressure values, correction of blood pressure values taking into account variations due to the posture of the subject Is possible.

  The posture detection unit detects whether the subject's midline is vertical or horizontal, and the blood pressure correction unit detects that the subject's midline is vertical. In some cases, a corrected hydrostatic pressure value is calculated by adding a preset hydrostatic pressure correction value to the blood pressure value measured by the blood pressure measuring means, and the posture detecting means detects that the midline of the subject is horizontal. In some cases, the blood pressure value measured by the blood pressure measuring means is preferably used as the corrected blood pressure value.

  By detecting whether the midline of the subject is vertical or horizontal, it is possible to detect whether the outer ear is at a higher position than the heart or at the same horizontal position. If the outer ear is higher than the heart, a hydrostatic pressure difference is generated between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. On the other hand, if the outer ear is at the same horizontal position as the heart, there is no hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. Thus, by detecting whether the midline of the subject is vertical or horizontal, there is a hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. The occurrence can be detected. As a result, when a hydrostatic pressure difference has occurred, a preset hydrostatic pressure difference is added to the blood pressure value measured in the outer ear, and the blood pressure value measured in the outer ear is measured at the heart height. Can be corrected.

  The posture detection means detects an inclination angle between a median line and a vertical line of the subject, and the blood pressure correction means detects a distance between the heart of the subject measured in advance and the blood pressure measurement means, and the posture detection. The ratio of the height difference between the heart of the subject and the blood pressure measuring means with respect to the distance is calculated from the inclination angle detected by the means, and the product of a preset hydrostatic pressure correction value and the ratio of the height difference is calculated as the blood pressure. The corrected blood pressure value is preferably calculated by adding to the blood pressure value measured by the measuring means.

  By detecting the tilt angle between the subject's midline and vertical line, the difference in height between the subject's heart and outer ear is calculated, and the blood pressure measured at the outer ear and the blood pressure measured at the heart height The hydrostatic pressure difference from the value can be calculated. Thereby, since the blood pressure value can be corrected according to the generated hydrostatic pressure difference, the blood pressure value measured at the outer ear can be more accurately corrected to the blood pressure value measured at the height of the heart.

但し、ａ_ｎは所定の係数、ｎは正整数、ｘは前記血圧測定手段の測定した血圧値、ｂ（ｈ）は前記高低差ｈに対する補正量である。 Further, the sphygmomanometer according to the present invention includes a blood pressure measurement unit that measures a blood pressure value by compressing a part of an artery of the subject, and a posture detection unit that detects an inclination angle between the midline and the vertical line of the subject. The height difference h between the subject's heart and the blood pressure measuring means is calculated from the previously measured distance between the subject's heart and the blood pressure measuring means and the inclination angle detected by the posture detecting means, Blood pressure correction means for calculating a corrected blood pressure value y corrected by the above.

However, a _n predetermined coefficients, n represents a positive integer, x is a blood pressure value measured in the blood pressure measuring means, b (h) is a correction amount for the height difference h.

  By correcting the blood pressure value measured at the outer ear to the blood pressure value measured at the height of the heart using Equation 1 including the height difference h between the heart and the outer ear of the subject, a more accurate corrected blood pressure value can be obtained. Can be calculated. For example, the blood pressure value measured by the upper arm at the heart level can be corrected.

  In Equation 1, n = 1 may be set.

  Since n = 1 in Equation 1, Equation 1 can be a linear function. Since the corrected blood pressure value can be calculated by a simple proportional relationship, the circuit for calculating the corrected blood pressure value can be easily designed.

In the formula 1, b (h) = b ₁ h may be set. Here, b ₁ is a correction coefficient for the height difference h.

  The correction amount b (h) is a correction amount for the height difference h. By using the correction amount b (h) as a function of the height difference h, it is possible to calculate a corrected blood pressure value y in which the hydrostatic pressure difference is corrected more accurately.

  Further, the sphygmomanometer according to the present invention is a blood pressure measurement unit that measures a blood pressure value by compressing a part of an artery of the subject, a posture detection unit that detects the posture of the subject, and a detection by the posture detection unit. Pressure correction means for correcting a measurement start pressure value for starting pressurization or pressure reduction among pressures compressed by the blood pressure measurement means based on the posture.

  The measurement start pressure value is a measurement start pressure value corrected according to the detected posture. In this way, the blood pressure value can be efficiently measured by pressing the subject with the measurement start pressure value corrected according to the detected posture.

  The posture detection means detects whether the midline of the subject is vertical or horizontal, and the pressure correction means detects that the midline of the subject is vertical When the posture detection unit detects that the preset hydrostatic pressure correction value is subtracted from the measurement start pressure value to calculate a corrected measurement start pressure value and the midline of the subject is horizontal. It is preferable that the measurement start pressure value is a corrected measurement start pressure value.

  By detecting whether the midline of the subject is vertical or horizontal, it is possible to detect whether the outer ear is at a higher position than the heart or at the same horizontal position. If the outer ear is higher than the heart, a hydrostatic pressure difference is generated between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. On the other hand, if the outer ear is at the same horizontal position as the heart, there is no hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. Thus, by detecting whether the subject's midline is vertical or horizontal, there is a hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. The occurrence can be detected. As a result, the blood pressure value can be measured by pressing the outer ear of the subject with the measurement start pressure value reduced by a preset hydrostatic pressure difference, and thus the blood pressure value can be measured efficiently.

  The posture detection means detects an inclination angle between a median line and a vertical line of the subject, and the pressure correction means detects a distance between the heart of the subject and the blood pressure measurement means, which has been measured in advance, and the posture detection. The ratio of the height difference between the heart of the subject and the blood pressure measuring means with respect to the distance is calculated from the inclination angle detected by the means, and the product of a preset hydrostatic pressure correction value and the ratio of the height difference is measured. It is preferable to subtract from the start pressure value to obtain a corrected measurement start pressure value.

  By detecting the tilt angle between the subject's midline and vertical line, the difference in height between the subject's heart and outer ear is calculated, and the blood pressure measured at the outer ear and the blood pressure measured at the heart height The hydrostatic pressure difference from the value can be calculated. Thereby, since the measurement start pressure value can be corrected according to the generated hydrostatic pressure difference, the blood pressure value can be measured more efficiently.

  The blood pressure measurement means includes: a light emitting element that emits light toward a part of an artery of the subject; and a light that the light emitted from the light emitting element transmits a part of the subject or a part of the subject It is preferable to detect a pulse wave with a light receiving element that receives light scattered by the inner wall of the light source.

  When the blood pressure measuring means detects the pulse wave using the light emitting element and the light receiving element, the blood pressure value can be measured from the peripheral blood vessels running in the outer ear.

  The blood pressure correction method according to the present invention measures a blood pressure value by compressing a part of an artery of a subject, detects the posture of the subject, and corrects the measured blood pressure value based on the detected posture. Then, a corrected blood pressure value is calculated.

  By correcting blood pressure values measured at the outer ear to blood pressure values measured at the height of the heart according to the posture detected at the same time as the measurement of blood pressure values, correction of blood pressure values taking into account variations due to the posture of the subject Is possible.

  In detecting the posture of the subject, it is detected whether the midline of the subject is vertical or horizontal, and in calculating the corrected blood pressure value, the subject's posture detected by detecting the posture of the subject is detected. When the midline is vertical, a corrected blood pressure value is calculated by adding a preset hydrostatic pressure correction value to the measured blood pressure value, and the midline of the subject detected by detecting the posture of the subject is When it is horizontal, the measured blood pressure value is preferably used as a corrected blood pressure value.

  By detecting whether the midline of the subject is vertical or horizontal, it is possible to detect whether the outer ear is at a higher position than the heart or at the same horizontal position. If the outer ear is higher than the heart, a hydrostatic pressure difference is generated between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. On the other hand, if the outer ear is at the same horizontal position as the heart, there is no hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. Thus, by detecting whether the subject's midline is vertical or horizontal, there is a hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. The occurrence can be detected. As a result, when a hydrostatic pressure difference has occurred, a preset hydrostatic pressure difference is added to the blood pressure value measured in the outer ear, and the blood pressure value measured in the outer ear is measured at the heart height. Can be corrected.

  In detecting the posture of the subject, the inclination angle between the midline and vertical line of the subject is detected, and in calculating the corrected blood pressure value, the heart of the subject measured in advance and a part of the subject The ratio of the height difference between the heart of the subject and a part of the subject with respect to the distance is calculated from the distance to the distance and the inclination angle detected by detecting the posture of the subject, and a preset hydrostatic pressure correction is performed. It is preferable to calculate a corrected blood pressure value by adding the product of the value and the ratio of the height difference to the measured blood pressure value.

  By detecting the tilt angle between the subject's midline and vertical line, the difference in height between the subject's heart and outer ear is calculated, and the blood pressure measured at the outer ear and the blood pressure measured at the heart height The hydrostatic pressure difference from the value can be calculated. Thereby, since the blood pressure value can be corrected according to the generated hydrostatic pressure difference, the blood pressure value measured at the outer ear can be more accurately corrected to the blood pressure value measured at the height of the heart.

但し、ａ_ｎは所定の係数、ｎは正整数、ｘは前記測定した血圧値、ｂ（ｈ）は前記高低差ｈに対する補正量である。 The blood pressure correction method according to the present invention measures a blood pressure value by compressing a part of an artery of a subject, detects an inclination angle between a midline and a vertical line of the subject, A corrected blood pressure obtained by calculating a height difference h between the subject's heart and a part of the subject from the distance between the subject's heart and a part of the subject and the detected inclination angle, and correcting the difference by Equation (2). The value y is calculated.

However, a _n predetermined coefficients, n represents a positive integer, x is a blood pressure value the measurement, b (h) is a correction amount for the height difference h.

  By correcting the blood pressure value measured at the outer ear to the blood pressure value measured at the height of the heart using Equation 2 including the height difference h between the heart and the outer ear of the subject, a more accurate corrected blood pressure value can be obtained. Can be calculated.

  In Equation 2, n = 1 may be set.

  Since n = 1 in Equation 2, Equation 2 becomes a linear function. Since the corrected blood pressure value can be calculated by a simple proportional relationship, the circuit for calculating the corrected blood pressure value can be easily designed.

In the equation 2, b (h) = b ₁ h may be set. Here, b ₁ is a correction coefficient for the height difference h.

  The correction amount b (h) is a correction amount for the height difference h. The height difference h includes a hydrostatic pressure difference between the subject's heart and the outer ear. By using this hydrostatic pressure difference as a function of the height difference h, it is possible to calculate a corrected blood pressure value y that more accurately corrects the hydrostatic pressure difference of the blood pressure value measured in the outer ear.

  In the measurement start pressure correction method according to the present invention, when the blood pressure value is measured by compressing a part of the artery of the subject, the pressure of the subject is compressed after detecting the posture of the subject. Among them, the measurement start pressure value for starting pressurization or decompression is corrected based on the detected posture.

  The measurement start pressure value is a measurement start pressure value corrected according to the detected posture. In this way, the blood pressure value can be efficiently measured by measuring the blood pressure by pressing the outer ear of the subject with the measurement start pressure value corrected according to the detected posture.

  In the detection of the posture of the subject, it is detected whether the midline of the subject is vertical or horizontal, and in the correction of the measurement start pressure value, the subject detected by detecting the posture of the subject When the midline of the subject is vertical, a corrected measurement start pressure value is calculated by subtracting a preset hydrostatic pressure correction value from the measurement start pressure value, and the subject detected by detecting the posture of the subject is calculated. When the median line is horizontal, the measurement start pressure value is preferably set as a corrected measurement start pressure value.

  By detecting whether the midline of the subject is vertical or horizontal, it is possible to detect whether the outer ear is at a higher position than the heart or at the same horizontal position. If the outer ear is higher than the heart, a hydrostatic pressure difference is generated between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. On the other hand, if the outer ear is at the same horizontal position as the heart, there is no hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. Thus, by detecting whether the subject's midline is vertical or horizontal, there is a hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart. The occurrence can be detected. As a result, the blood pressure value can be measured by pressing the outer ear of the subject with the measurement start pressure value reduced by a preset hydrostatic pressure difference, and thus the blood pressure value can be measured efficiently.

  In detecting the posture of the subject, the inclination angle between the midline and vertical line of the subject is detected, and in correcting the measurement start pressure value, one of the heart of the subject and the subject measured in advance is detected. The ratio of the height difference between the heart of the subject and a part of the subject with respect to the distance is calculated from the distance to the part and the inclination angle detected by detecting the posture of the subject, and a preset hydrostatic pressure is calculated. It is preferable to calculate a corrected measurement start pressure value by subtracting the product of the correction value and the ratio of the height difference from the measurement start pressure value.

  By detecting the tilt angle between the subject's midline and vertical line, the difference in height between the subject's heart and outer ear is calculated, and the blood pressure measured at the outer ear and the blood pressure measured at the heart height The hydrostatic pressure difference from the value can be calculated. Thereby, since the measurement start pressure value can be corrected according to the generated hydrostatic pressure difference, the blood pressure value can be measured more efficiently.

  The present invention can correct the blood pressure value measured at the outer ear to the blood pressure value measured at the height of the heart according to the detected posture of the subject. In particular, by detecting the level of the heart and the outer ear, it is possible to correct fluctuations in blood pressure values due to the hydrostatic pressure difference generated in the posture of the subject.

  In addition, it is possible to efficiently measure the blood pressure value by detecting the posture of the subject and changing the measurement start pressure value that compresses the outer ear of the subject when measuring the blood pressure value.

Hereinafter, the present invention will be described in detail with reference to the drawings, but the present invention is not construed as being limited to these descriptions.
(Embodiment 1)
FIG. 1 is a circuit diagram illustrating an example of a sphygmomanometer according to the first embodiment. The sphygmomanometer shown in FIG. 1 includes a blood pressure measurement unit 11 that measures a blood pressure value 1 by compressing an artery of an outer ear of a subject (not shown), a posture detection unit 21 that detects a posture 2 of the subject, and a blood pressure measurement. Blood pressure correction means 31 for correcting the blood pressure value 1 measured by the means 11 based on the posture 2 detected by the attitude detection means 21 and calculating the corrected blood pressure value 3.

  The blood pressure measurement means 11 measures the blood pressure value 1 by compressing the artery of the outer ear of the subject. The blood pressure measurement means 11 includes a device that presses an artery of a test part, detects a pulse wave of the test part pressed and pressed, and measures a blood pressure value from the pulse wave and the pressed pressure.

  For example, the blood pressure measurement unit 11 emits light toward the artery of the outer ear of the subject, and the light emitted from the light emitting element is scattered by the light transmitted through the outer ear of the subject or the inner wall of the outer ear of the subject. An example of detecting a pulse wave with a light receiving element that receives light can be given. As the light emitting element, for example, an edge emitting laser, a surface emitting laser, or an LED can be used. The characteristics such as the wavelength, amplitude, and phase of the emitted light are not limited. For example, it may be light scattered by blood vessels included in the measurement site. Moreover, the light scattered by fluids, such as hemoglobin which flows through the inside of the blood vessel of a measurement site | part, may be sufficient. As the light receiving element, for example, a photodiode such as a silicon photodiode, a photoelectric conducting element such as CdS, a photoelectric tube, a position sensor, a CCD, a MOS, or the like can be used. The characteristics such as the wavelength, amplitude, and phase of the received light are not limited. Further, the light emitting element and the light receiving element may be Doppler radars. When the light receiving element detects a pulse wave, a blood pressure value can be measured from a peripheral blood vessel running in the outer ear.

  In addition to the above, examples that can detect pulse waves include those that detect Korotkoff sounds, and those that detect pressure or vibration due to pulsation and measure pressure pulses.

  The method for compressing the test part is not limited, and for example, an air cuff can be exemplified. Moreover, you may press using a mechanical actuator. The method for measuring the pressure for pressing the test part is not limited, and for example, a piezoelectric sensor can be exemplified. If it is an air cuff, the air pressure in the cuff may be measured.

  An example of a method in which the blood pressure measurement unit 11 measures the blood pressure value 1 will be described with reference to FIG. FIG. 2 is a graph showing an example of a pulse wave detected by the blood pressure measurement means 11, where (a) shows the time transition of pressure and (b) shows the time transition of pulsation waveform amplitude. FIG. 2A shows a periodic internal artery pressure 61 of the test part due to the heartbeat and a pressing pressure 51 by which the blood pressure measurement means 11 presses the test part. FIG. 2B shows a pulsation waveform 71 detected by the blood pressure measurement means 11. The blood pressure measuring means 11 first increases the pressure that presses the test part having the artery of the outer ear of the subject, and presses the test part to a pressure P0 that stops the blood flow in the artery. This pressure P0 is set as a measurement start pressure value P0. The time at this time is T0, and at time T0, the pulsation waveform 71 shown in FIG. The blood pressure measurement means 11 gradually decreases the pressing pressure 51 that presses the test portion at the time T0. Since the blood begins to flow to the test portion at time T1 when the pressing pressure 51 becomes equal to the maximum value of the intra-arterial pressure 61 that pulsates due to the heartbeat, a pulsating waveform 71 appears. The pressing pressure 51 at the time T1 becomes the maximum blood pressure value P1. The amplitude of the pulsation waveform amplitude 71 gradually increases from time T1, and reaches the maximum at time T2. The pressing pressure 51 at this time T2 becomes the diastolic blood pressure value P2 that is the lowest value of the arterial pressure 61. When the pressing pressure 51 is further decreased, the pulse wave signal amplitude 71 gradually decreases, and then the upper end portion becomes a constant value and shows a flat state. After a slight time delay, the lower end of the pulse wave signal amplitude 71 is reached at time T3. The part also changes to a constant value. The pressing pressure 51 at the time T3 becomes the minimum blood pressure value P3. As described above, the maximum blood pressure value P1, the diastolic blood pressure value P2, and the minimum blood pressure value P3 can be measured. The method for measuring the blood pressure value is not limited to the above, and the pressure pressure 51 may be gradually increased.

  The posture detection means 21 detects the posture of the subject, and can be exemplified by applying a gravity sensor that detects the direction of gravity acceleration. The posture detection means 21 may be capable of detecting whether the midline of the subject is parallel or perpendicular to the direction of gravity acceleration by detecting the direction of gravity acceleration, and this is the first posture detection means. By detecting whether the midline of the subject is vertical or horizontal, it is possible to detect whether the outer ear is at a higher position than the heart or at the same horizontal position. The posture detection means 21 may detect a tilt angle between the midline of the subject and a vertical line parallel to the direction of gravity acceleration by detecting the direction of gravity acceleration. Detecting means. By detecting the inclination angle between the midline and the vertical line of the subject, the height difference between the heart and the outer ear of the subject can be calculated.

  The blood pressure correction unit 31 in FIG. 1 calculates a corrected blood pressure value 3 by correcting the blood pressure value 1 based on the posture 2 detected by the posture detection unit 21.

  A first embodiment of the blood pressure correction means 31 shown in FIG. 1 will be described with reference to FIGS. 3A and 3B are schematic views of the subject 91 in which the blood pressure measuring means 11 is attached to the outer ear 42 of the subject 91, where FIG. 3A is a posture in which the midline of the subject is vertical, and FIG. 3B is a subject. Shows a posture in which the midline of is horizontal. When the midline 101 of the subject 91 is vertical, the midline 101 of the subject 91 is parallel to the vertical line 102 parallel to the gravity direction 103, as shown in FIG. At this time, the heart 41 of the subject 91 is at a lower position than the blood pressure measurement means 11 attached to the outer ear 42 of the subject 91. When the midline 101 of the subject 91 is horizontal, the midline 101 of the subject 91 is parallel to the horizontal line 104 as shown in FIG. At this time, the heart 41 of the subject 91 is at substantially the same horizontal position as the blood pressure measurement means 11 attached to the outer ear 42.

  The posture detection unit 21 detects whether the midline 101 of the subject 91 is vertical or horizontal, and the blood pressure correction unit 31 determines that the midline 101 of the subject 91 is vertical. When detected, a preset hydrostatic pressure correction value is added to the blood pressure value 1 measured by the blood pressure measuring means 11 to calculate a corrected blood pressure value 3, thereby detecting the posture that the midline 101 of the subject 91 is horizontal. When the means 21 detects, the blood pressure value 1 measured by the blood pressure measuring means 11 is set as the corrected blood pressure value 3. At this time, posture 2 shown in FIG. 1 is information indicating whether the midline 101 of the subject 91 detected by the posture detecting means 21 is vertical or horizontal.

  That is, in the blood pressure correction method according to the first form of the blood pressure correction means 31, in the detection of the posture of the subject, it is detected whether the midline 101 of the subject 91 is vertical or horizontal, and the corrected blood pressure value is calculated. Then, when the subject's midline 101 detected by detecting the posture of the subject is vertical, a corrected blood pressure value 3 is calculated by adding a preset hydrostatic pressure correction value to the measured blood pressure value 1, When the midline 101 of the subject 91 detected by detecting the posture of the specimen is horizontal, the measured blood pressure value 1 is set as the corrected blood pressure value 3.

  In this case, the posture detection means 21 can be the same as the first posture detection means described above. As shown in FIG. 3A, if the outer ear 42 is at a higher position than the heart 41, the static blood pressure between the blood pressure value 1 measured at the outer ear 42 and the blood pressure value measured at the height of the heart 42 is static. Water pressure difference occurs. On the other hand, as shown in FIG. 3B, if the outer ear is at the same horizontal position as the heart, the blood pressure value measured at the outer ear 42 and the blood pressure value measured at the height of the heart 42 are static. There is no water pressure difference. The blood pressure value 1 measured in the posture shown in FIG. 3A becomes lower due to the influence of the generated hydrostatic pressure difference. By adding a preset hydrostatic pressure correction value to the blood pressure value 1 measured in this posture, the blood pressure value measured at the height of the heart 41 can be corrected. The hydrostatic pressure correction value can be a hydrostatic pressure difference between the heart 41 and the outer ear 42. Since the hydrostatic pressure difference depends on the distance between the heart 41 and the outer ear 42, the preset hydrostatic pressure correction value may be varied according to the subject. As described above, the hydrostatic pressure difference between the blood pressure value measured at the outer ear and the blood pressure value measured at the height of the heart is detected by detecting whether the midline of the subject is vertical or horizontal. Can be detected. As a result, when a hydrostatic pressure difference has occurred, a preset hydrostatic pressure difference is added to the blood pressure value measured in the outer ear, and the blood pressure value measured in the outer ear is measured at the heart height. Can be corrected.

  A second embodiment of the blood pressure correction means 31 shown in FIG. 1 will be described with reference to FIGS. 4A and 4B are schematic views of the subject 91 in which the blood pressure measuring means 11 is mounted on the outer ear 42 of the subject 91, where FIG. 4A is a posture in which the midline 101 of the subject 91 is vertical, and FIG. A posture in which the midline 101 of the subject 91 is at an inclination angle Q with respect to the vertical line 102 is shown. The subject 91 in FIG. 4A is upright, and the midline 101 of the subject 91 is parallel to the vertical line 102 parallel to the gravity direction 103. At this time, the height difference h between the heart 41 and the outer ear 42 is the distance L between the heart 41 and the outer ear 42. The subject 91 in FIG. 4B has a posture in which the upper body is tilted forward. The distance projected on the vertical line between the heart 41 and the outer ear 42 at this time is the height difference h.

  The posture detection means 21 detects the inclination angle Q between the median line 101 and the vertical line 102 of the subject 91, and the blood pressure correction means 31 measures the distance between the heart 41 of the subject 91 and the blood pressure measurement means 11 measured in advance. The ratio i of the height difference h between the heart 41 of the subject 91 and the blood pressure measuring means 11 with respect to the distance L is calculated from L and the inclination angle Q detected by the posture detecting means 21, and the preset hydrostatic pressure correction value and the height difference are calculated. The corrected blood pressure value 3 is calculated by adding the product of the ratio i of h to the blood pressure value 1 measured by the blood pressure measuring means 11. At this time, posture 2 shown in FIG. 1 is an inclination angle Q between the midline 101 and the vertical line 102 of the subject 91, and the posture detection means 21 outputs the inclination angle Q as posture 2 to the blood pressure measurement means 12. .

  That is, the blood pressure correction method according to the second form of the blood pressure correction means 31 detects the inclination angle Q between the midline 101 and the vertical line 102 of the subject 91 in detecting the posture of the subject, In the calculation, the heart 41 of the subject and the subject with respect to the distance L from the previously measured distance L between the heart 41 of the subject 91 and the outer ear 42 of the subject 91 and the inclination angle Q detected by detecting the posture of the subject. The ratio i of the height difference h with the outer ear 42 is calculated, and a corrected blood pressure value 3 is calculated by adding the product of a preset hydrostatic pressure correction value and the ratio i of the height difference h to the measured blood pressure value 1. .

  The ratio i of the height difference h can be calculated by calculating the height difference h from the distance L and the inclination angle Q using a trigonometric function and determining the ratio of the height difference h to the distance L. In this case, the posture detection means 21 can be the same as the second posture detection means described above. By integrating the ratio i of the height difference h and a preset hydrostatic pressure correction value, the hydrostatic pressure difference corresponding to the height difference h between the heart 41 and the outer ear 42 can be calculated. The hydrostatic pressure correction value can be a hydrostatic pressure difference between the heart 41 and the outer ear 42. Since the hydrostatic pressure difference depends on the distance between the heart 41 and the outer ear 42, the preset hydrostatic pressure correction value may vary depending on the subject. Thus, since the blood pressure value 1 can be corrected according to the height difference h between the heart 41 and the outer ear 42, the blood pressure value 1 measured at the outer ear 42 is more accurately measured at the height of the heart 41. Can be corrected.

  Further, a third embodiment of the blood pressure correction means 31 shown in FIG. 1 will be described with reference to FIGS. The sphygmomanometer including the third form of the blood pressure correction means 31 includes a blood pressure measurement means 11 that measures the blood pressure value 1 by compressing the artery of the outer ear 42 of the subject 91, a midline 101 and a vertical line 102 of the subject 91, Posture detecting means 21 for detecting the inclination angle Q of the subject, the heart 41 of the subject 91 from the previously measured distance L between the heart 41 of the subject 91 and the blood pressure measuring means 11 and the inclination angle Q detected by the posture detecting means 21. And a blood pressure correction means 31 for calculating a corrected blood pressure value y corrected by Equation (3).

但し、ａ_ｎは所定の係数、ｎは正整数、ｘは測定された血圧値１、ｂ（ｈ）は高低差ｈに対する補正量である。 That is, the blood pressure correction method including the third form of the blood pressure correction means 31 measures the blood pressure value 1 by compressing the artery of the outer ear 42 of the subject 91, and the inclination between the midline 101 and the vertical line 102 of the subject 91. The angle Q is detected, and the heart 41 of the subject 91 and the outer ear 42 of the subject 91 are detected from the previously measured distance L between the heart 41 of the subject 91 and the outer ear 42 of the subject 91 and the detected inclination angle Q. A height difference h is calculated, and a corrected blood pressure value y corrected by Equation 3 is calculated.

However, a _n predetermined coefficients, n represents a positive integer, x is the measured blood pressure values 1, b (h) is a correction amount for the height difference h.

  The blood pressure correction means 31 of the third form calculates the corrected blood pressure value y by the general formula including the height difference h described with reference to FIG.

The predetermined coefficient a _n (n = 1, 2,..., N) can be determined by measuring in advance the correlation between the blood pressure value measured by the blood pressure measurement means 11 and the blood pressure value measured by the reference measurement method. it can. An example of the reference measurement method is a blood pressure value measured at the upper arm of the height of the heart 41. Since the correction amount due to the height difference is corrected by b (h), the measurement of the blood pressure value by the blood pressure measuring means 11 is preferably measured at the same horizontal position as the heart 41.

Note that in the above Equation 3, n = 1 may be used. Since n = 1, Equation 3 can be made a linear function. As a result, the corrected blood pressure value can be calculated with a simple proportional relationship, which facilitates the design of a circuit for calculating the corrected blood pressure value. The predetermined coefficient a _n includes a blood pressure ratio of arterial inner diameter. For example, it is the blood pressure ratio between the arterial inner diameter of the upper arm and the arterial inner diameter of the outer ear. Furthermore, predetermined coefficient a _n may be as different coefficients depending on the subject may be the same coefficients for the plurality of subjects.

  The correction amount b (h) is a correction amount for the height difference h and includes a hydrostatic pressure difference. The hydrostatic pressure difference is a hydrostatic pressure difference between a blood pressure value measured at the outer ear and a blood pressure value measured at the height of the heart. The correction amount b (h) may be a fixed value set in advance, or may be a function of the height difference h.

The correction amount b (h) may be, for example, b (h) = b ₁ h. Here, b ₁ is a correction coefficient for the height difference h. By using the correction amount b (h) as a function of the height difference h, it is possible to calculate a corrected blood pressure value y in which the hydrostatic pressure difference is corrected more accurately. The correction coefficient b ₁ may be a different coefficient depending on the subject, or may be the same coefficient for a plurality of subjects.

  In this way, the blood pressure value measured at the outer ear is corrected to the blood pressure value measured at the height of the heart using the general formula shown in Equation 3 including the height difference h between the heart and the outer ear of the subject. Thus, a more accurate corrected blood pressure value can be calculated. For example, the blood pressure value measured by the upper arm (not shown) at the height of the heart 41 can be corrected.

  Note that the sphygmomanometer according to the present embodiment starts measurement to start pressurization or depressurization among pressures pressed by the blood pressure measurement unit based on the posture or inclination angle detected by the posture detection unit 21 described in the second embodiment described later. Pressure correction means for correcting the pressure value may be included. Further, the blood pressure value 1 measured by the blood pressure measuring means 11 and the corrected blood pressure value 3 corrected to the blood pressure value at the height of the heart 1 can be output / displayed.

  As described above, the sphygmomanometer of the first embodiment measures the blood pressure value by compressing the artery of the outer ear of the subject, detects the posture of the subject, and determines the detected posture of the measured blood pressure value. The corrected blood pressure value is calculated based on the correction. The posture includes an inclination angle. In this way, the blood pressure value measured at the outer ear is corrected to the blood pressure value measured at the height of the heart according to the posture detected simultaneously with the blood pressure value measurement, thereby taking into account variations due to the posture of the subject. The blood pressure value can be corrected.

(Embodiment 2)
FIG. 5 is a circuit diagram illustrating an example of a sphygmomanometer according to the second embodiment. The sphygmomanometer shown in FIG. 2 includes a blood pressure measurement unit 12 that measures a blood pressure value 5 by compressing an artery in the outer ear of a subject (not shown), a posture detection unit 21 that detects the posture of the subject, and a posture detection unit. Pressure correction means for outputting to the blood pressure measurement means 12 a corrected measurement start pressure value 4 obtained by correcting the measurement start pressure value for starting pressurization or decompression out of the pressures compressed by the blood pressure measurement means 12 based on the posture 2 detected by 21. 35.

  As the blood pressure measurement unit 12 and the posture detection unit 21, the same ones as those described in the first embodiment can be used. However, in the blood pressure measurement means 12, the measurement start pressure value described in FIG. 2 for starting pressurization or pressure reduction is the corrected measurement start pressure value 4 output from the pressure correction means 35.

  The pressure correction unit 35 corrects the measurement start pressure value P0 described in FIG. 2 of the first embodiment based on the posture 2 detected by the posture detection unit 21.

  A first embodiment of the pressure correction means 35 shown in FIG. 5 will be described with reference to FIGS. FIG. 3 is a schematic diagram of the subject 91 in which the blood pressure measuring means 11 is mounted on the outer ear 42 of the subject 91 as described above, and (a) is a posture in which the midline of the subject is vertical, ( b) shows the posture in which the midline of the subject is horizontal. The posture detection unit 21 detects whether the midline 101 of the subject 91 is vertical or horizontal, and the pressure correction unit 35 determines that the midline 101 of the subject 91 is vertical. When detected, the preset hydrostatic pressure correction value is subtracted from the measurement start pressure value to calculate a corrected measurement start pressure value 4, and the posture detection means 21 indicates that the midline 101 of the subject 91 is the horizontal 104. When detected, the measurement start pressure value is set to a corrected measurement start pressure value 4. At this time, posture 2 shown in FIG. 5 is information indicating whether the midline 101 of the subject 91 detected by the posture detection means 21 is vertical or horizontal.

  That is, in the measurement start pressure correction method according to the first form of the pressure correction means 35, in detecting the posture of the subject, it is detected whether the midline 101 of the subject 91 is vertical or horizontal, and the measurement start pressure is detected. In the correction of the value, when the median line 101 of the subject 91 detected by detecting the posture of the subject is vertical, a corrected hydrostatic pressure correction value is subtracted from the measurement start pressure value to obtain a corrected measurement start pressure value 4. When the midline 101 of the subject 91 detected by the detection of the posture of the subject is horizontal, the measurement start pressure value is set as the corrected measurement start pressure value 4.

  In this case, the posture detection means 21 can be the same as the first posture detection means described above. As shown in FIG. 3A, if the outer ear 42 is at a higher position than the heart 41, the static blood pressure between the blood pressure value 1 measured at the outer ear 42 and the blood pressure value measured at the height of the heart 42 is static. Water pressure difference occurs. On the other hand, as shown in FIG. 3B, if the outer ear is at the same horizontal position as the heart, the blood pressure value measured at the outer ear 42 and the blood pressure value measured at the height of the heart 42 are static. There is no water pressure difference. The blood pressure value 1 in the posture shown in FIG. 3A is lower than the blood pressure value measured at the height of the heart 41 due to the influence of the hydrostatic pressure difference. The blood pressure measuring means 12 can stop the blood flow of the artery even if the outer ear of the subject is compressed with the corrected measurement start pressure value 4 which is reduced by the hydrostatic pressure difference. Since the measurement start pressure value is the maximum pressure that presses the test part when measuring the blood pressure value, the measurement of the blood pressure value can be made more efficient if the measurement start pressure value can be lowered. The hydrostatic pressure correction value can be a hydrostatic pressure difference between the heart 41 and the outer ear 42. Since the hydrostatic pressure difference depends on the distance between the heart 41 and the outer ear 42, the preset hydrostatic pressure correction value may be varied according to the subject. From the above, a hydrostatic pressure difference occurs between the blood pressure value measured at the outer ear and the blood pressure value measured at the heart level by detecting whether the subject's midline is vertical or horizontal Can be detected. As a result, the blood pressure value can be measured by pressing the outer ear of the subject with the measurement start pressure value reduced by a preset hydrostatic pressure difference, and thus the blood pressure value can be measured efficiently.

  A second embodiment of the pressure correction means 35 shown in FIG. 5 will be described with reference to FIGS. 4 is a schematic diagram of the subject 91 in which the blood pressure measuring means 11 is mounted on the outer ear 42 of the subject 91 as described above, and FIG. 4A is a posture in which the midline 101 of the subject 91 is vertical. (B) shows the posture in which the midline 101 of the subject 91 is at an inclination angle Q with respect to the vertical line 102. The subject 91 in FIG. 4A is upright, and the midline 101 of the subject 91 is parallel to the vertical line 102 parallel to the gravity direction 103. At this time, the height difference h between the heart 41 and the outer ear 42 is the distance L between the heart 41 and the outer ear 42. The subject 91 in FIG. 4B has a posture in which the upper body is tilted forward. The distance projected on the vertical line between the heart 41 and the outer ear 42 at this time is the height difference h.

  The posture detection means 21 detects the inclination angle Q between the median line 101 and the vertical line 102 of the subject 91, and the pressure correction means 35 measures the distance between the heart 41 of the subject 91 and the blood pressure measurement means 12 measured in advance. Then, the ratio i of the height difference h between the heart 41 of the subject 91 and the blood pressure measurement means 11 with respect to the distance L is calculated from the inclination angle Q detected by the posture detection means 21, and the preset hydrostatic pressure correction value and the height difference h are calculated. Is subtracted from the measurement start pressure value to obtain a corrected measurement start pressure value of 4. At this time, posture 2 shown in FIG. 5 is an inclination angle Q between the midline 101 and the vertical line 102 of the subject 91, and the posture detection means 21 outputs the inclination angle Q as posture 2 to the blood pressure correction means 31. .

  That is, the measurement start pressure correction method according to the second embodiment of the pressure correction means 35 detects the inclination angle Q between the midline 101 and the vertical line 102 of the subject 91 and detects the measurement start pressure in detecting the posture of the subject. In the correction of the values, the heart 91 of the subject 91 with respect to the distance L from the previously measured distance L between the heart 41 of the subject 91 and the outer ear 42 of the subject 91 and the inclination angle Q detected by detecting the posture of the subject. 41 is calculated and the ratio i of the height difference h between the outer ear 42 of the subject 91 is calculated, and the correction measurement is started by subtracting the product of the preset hydrostatic pressure correction value and the ratio i of the height difference h from the measurement start pressure value. A pressure value of 4 is calculated.

  The ratio i of the height difference h can be calculated by calculating the height difference h using a trigonometric function of the distance L and the inclination angle Q and obtaining the ratio of the height difference h to the distance L. In this case, the posture detection means 21 can be the same as the second posture detection means described above. By integrating the ratio i of the height difference h and a preset hydrostatic pressure correction value, the hydrostatic pressure difference corresponding to the height difference h between the heart 41 and the outer ear 42 can be calculated. The hydrostatic pressure correction value can be a hydrostatic pressure difference between the heart 41 and the outer ear 42. Since the hydrostatic pressure difference depends on the distance between the heart 41 and the outer ear 42, the hydrostatic pressure correction value may vary depending on the subject. Thus, since the measurement start pressure value can be corrected according to the generated hydrostatic pressure difference, the blood pressure value can be measured more efficiently.

  As described above, the measurement start pressure correction method according to the present invention compresses the subject after detecting the posture of the subject when measuring the blood pressure value by compressing the artery of the outer ear of the subject. Among the pressures to be measured, the measurement start pressure value for starting pressurization or pressure reduction is corrected based on the detected posture. The posture includes an inclination angle. In this way, the blood pressure value can be efficiently measured by measuring the blood pressure by pressing the outer ear of the subject with the measurement start pressure value corrected according to the detected posture. The sphygmomanometer of this embodiment calculates a corrected blood pressure value by correcting the blood pressure value 1 measured by the blood pressure measurement unit 11 described in the first embodiment based on the posture 2 detected by the posture detection unit 21. Blood pressure correction means may be included.

  In the first embodiment and the second embodiment, the outer ear is described as an example of a part of the subject. However, a part of the subject may be the outer ear and / or the periphery thereof. Further, a part of the subject may be the ear canal and / or the pinna. Further, a part of the subject may be the tragus and / or its periphery.

  An embodiment in which a blood pressure value measured at the outer ear is corrected to a blood pressure value measured at the height of the heart will be described. The maximum blood pressure value P1 and the diastolic blood pressure value P2 were measured every 5 minutes in the outer ear, and the measurement results were compared with the brachial blood pressure values. The head position was also detected using a two-direction acceleration sensor (gravity sensor). The blood pressure value of the outer ear was measured by detecting the pulse wave with a photoelectric tube pulse wave sensor. The brachial blood pressure value was measured with a double cuff sphygmomanometer (Terumo ES-P1000). The subjects are 20 to 70 years old, 58 cases (25 men and 33 women). Moreover, the range of the blood pressure value was 86 to 202 mmHg for the maximum blood pressure value P1, and 48 to 126 mmHg for the diastolic blood pressure value P2.

の関係が成り立つとした。但し、Ａは動脈内径による血圧比率、Ｂは上腕と外耳との静水圧差である。まず、血圧比率Ａ及び静水圧差Ｂの平均値を求めた。最大血圧値Ｐ１での血圧比率Ａは１．３８±０．１７、拡張期血圧値Ｐ２での血圧比率Ａは１．３０±０．２７であり、静水圧差Ｂは２５±２．７ｍｍＨｇであった。これらの数値を用いて対象者の最大血圧値Ｐ１及び拡張期血圧値Ｐ２を算出したところ、上腕血圧値ＢＰｂと上腕血圧測定値ＢＰｂ’との差の平均は、最大血圧値Ｐ１で０．３±１４ｍｍＨｇ、拡張期血圧値Ｐ２で−２．５±２．７ｍｍＨｇであった。さらに、上腕血圧値ＢＰｂと上腕血圧測定値ＢＰｂ’との間に、最大血圧値Ｐ１で０．８６倍、拡張期血圧値Ｐ２で０．８１倍という相関関係があることが判明した。 Between the upper arm blood pressure value BPb and the outer ear blood pressure value BPe,

The relationship was established. However, A is the blood pressure ratio due to the inner diameter of the artery, and B is the hydrostatic pressure difference between the upper arm and the outer ear. First, the average value of the blood pressure ratio A and the hydrostatic pressure difference B was obtained. The blood pressure ratio A at the maximum blood pressure value P1 is 1.38 ± 0.17, the blood pressure ratio A at the diastolic blood pressure value P2 is 1.30 ± 0.27, and the hydrostatic pressure difference B is 25 ± 2.7 mmHg. there were. When the maximum blood pressure value P1 and the diastolic blood pressure value P2 of the subject were calculated using these numerical values, the average difference between the upper arm blood pressure value BPb and the upper arm blood pressure measurement value BPb ′ was 0.3 at the maximum blood pressure value P1. The diastolic blood pressure value P2 was −2.5 ± 2.7 mmHg. Furthermore, it has been found that there is a correlation between the upper arm blood pressure value BPb and the upper arm blood pressure measurement value BPb ′, which is 0.86 times at the maximum blood pressure value P1 and 0.81 times at the diastolic blood pressure value P2.

  From the above measurement, it can be seen that the brachial blood pressure measurement value BPb 'can be accurately calculated from the external ear blood pressure value BPe using Equation 4. By using the correlation between the upper arm blood pressure value BPb and the upper arm blood pressure measurement value BPb ', a more accurate upper arm blood pressure measurement value BPb' can be calculated. The blood pressure ratio A has slight individual differences, and it has been clarified that the accuracy of the upper arm blood pressure measurement value BPb 'is improved by setting the blood pressure ratio A for each subject. However, since the individual difference in the blood pressure ratio A is slight and there is no individual difference in the hydrostatic pressure difference B, the relative blood pressure value fluctuation can be measured with the blood pressure value corrected to the upper arm blood pressure value BPb.

  The sphygmomanometer for wearing the outer ear used in this example had a feeling of wearing the earpiece, and the burden at the time of cuff pressurization was also light. Furthermore, the movement of both upper limbs was free compared with the conventional blood pressure monitor, and there were much fewer troubles in daily life.

  Since the present invention corrects the measured value according to the posture of the subject, it can be used not only for blood pressure values but also for measured values of other biological information such as pulse waves, electrocardiograms, and body temperature. . Furthermore, it can also be used for cosmetic purposes, such as measuring the amount of moisture in the skin and measuring the amount of oil secreted from the scalp.

3 is a circuit diagram showing an example of a sphygmomanometer according to Embodiment 1. FIG. It is a graph which shows an example of the pulse wave which a blood-pressure measurement means detects, (a) shows the time transition of a pressure, (b) shows the time transition of a pulsation waveform amplitude. It is a schematic diagram of a subject in which blood pressure measuring means is attached to the outer ear, where (a) shows the posture in which the midline of the subject is vertical, and (b) shows the posture in which the midline of the subject is horizontal. FIG. 4 is a schematic diagram of a subject with blood pressure measurement means attached to the outer ear, where (a) is a posture in which the midline of the subject is vertical, and (b) is a tilt of the midline of the subject with respect to the vertical line. Indicates the posture. 6 is a circuit diagram showing an example of a sphygmomanometer according to Embodiment 2. FIG.

Explanation of symbols

1, 5 Blood pressure value 2 Posture 3 Blood pressure correction value 4 Measurement start pressure value 11, 12 Blood pressure measurement means 21 Posture detection means 31 Blood pressure correction means 35 Pressure correction means 41 Subject's heart 42 Subject's outer ear 51 Pressing pressure 61 Intra-arterial pressure 71 Pulsating waveform 91 Subject 101 Midline 102 Vertical line 103 Gravitational acceleration direction 104 Horizontal line L Distance h Height difference Q Inclination angle P0 Measurement start pressure value P1 High blood pressure value P2 Diastolic blood pressure value P3 Minimum blood pressure value T0, T1, T2, T3 time

Claims (24)

Blood pressure measuring means for measuring a blood pressure value by compressing a part of an artery of a subject;
Posture detection means for detecting an inclination angle between a midline and a vertical line of the subject;
The ratio of the height difference between the subject's heart and the blood pressure measuring means is calculated in advance from the pre-measured distance between the subject's heart and the blood pressure measuring means and the inclination angle detected by the posture detecting means. A sphygmomanometer comprising: a blood pressure correction unit that calculates a corrected blood pressure value by adding a product of the corrected hydrostatic pressure value and the ratio of the height difference to a blood pressure value measured by the blood pressure measurement unit. Blood pressure measuring means for measuring a blood pressure value by compressing a part of an artery of a subject;
Posture detection means for detecting an inclination angle between a midline and a vertical line of the subject;
The height difference h between the subject's heart and the blood pressure measuring means is calculated from the previously measured distance between the subject's heart and the blood pressure measuring means and the inclination angle detected by the posture detecting means. A blood pressure monitor comprising: a blood pressure correction unit that calculates a corrected blood pressure value y that has been corrected.

However, a _n predetermined coefficients, n represents a positive integer, x is a blood pressure value measured in the blood pressure measuring means, b (h) is a correction amount for the height difference h. In claim 2, the n = 1, a predetermined coefficient a ₁ is sphygmomanometer, which is a blood pressure ratio of arterial inner diameter. The sphygmomanometer according to claim 2, wherein b (h) = b ₁ h.
Here, b ₁ is a correction coefficient for the height difference h. Blood pressure measuring means for measuring a blood pressure value by compressing a part of an artery of a subject;
Posture detecting means for detecting the posture of the subject;
A sphygmomanometer, comprising: a pressure correction unit that corrects a measurement start pressure value for starting pressurization or depressurization among pressures compressed by the blood pressure measurement unit based on a posture detected by the posture detection unit. The posture detection means detects whether the midline of the subject is vertical or horizontal;
When the posture detection unit detects that the midline of the subject is vertical, the pressure correction unit subtracts a preset hydrostatic pressure correction value from the measurement start pressure value, thereby correcting the measurement start pressure value. The blood pressure according to claim 5 , wherein when the posture detecting means detects that the midline of the subject is horizontal, the measurement start pressure value is set as a corrected measurement start pressure value. Total. The posture detection means detects an inclination angle between a midline and a vertical line of the subject;
The pressure correction unit is configured to determine whether the heart of the subject and the blood pressure measurement unit are higher or lower with respect to the distance based on a previously measured distance between the heart of the subject and the blood pressure measurement unit and an inclination angle detected by the posture detection unit. the percentage difference is calculated, the product of a preset hydrostatic correction value and the ratio of the height difference to claim 5, characterized in that the correction measurement start pressure value is subtracted from the measurement start pressure value The sphygmomanometer described. The blood pressure measurement means includes: a light emitting element that emits light toward a part of an artery of the subject; and a light that the light emitted from the light emitting element transmits a part of the subject or a part of the subject The sphygmomanometer according to any one of claims 1 to 7 , wherein a pulse wave is detected by a light receiving element that receives light scattered by the inner wall. The sphygmomanometer according to any one of claims 1 to 8 , wherein a part of the subject is the outer ear and / or the periphery thereof. The sphygmomanometer according to any one of claims 1 to 8 , wherein a part of the subject is an external auditory canal and / or an auricle. The sphygmomanometer according to any one of claims 1 to 8 , wherein a part of the subject is a tragus and / or its periphery. A portion from the tilt angle of the heart and the subject of the subject and the distance and the detected midline and vertical line of the subject with the portion of the heart and the subject of the subject is measured Me pre The corrected blood pressure value is calculated by adding the product of the preset hydrostatic pressure correction value and the height difference ratio to the blood pressure value measured by compressing a part of the artery of the subject. Blood pressure correction method for calculating A portion from the tilt angle of the heart and the subject of the subject and the distance and the detected midline and vertical line of the subject with the portion of the heart and the subject of the subject is measured Me pre The blood pressure correction method of calculating the corrected blood pressure value y corrected by the formula 2 by calculating the height difference h of.

However, a _n predetermined coefficients, n represents a positive integer, x is the measured blood pressure values and compress the portion of the artery of the subject, b (h) is a correction amount for the height difference h. In claim 13, the blood pressure correction method and n = 1, a predetermined coefficient a ₁ is characterized in that a pressure ratio of arterial inner diameter. 14. The blood pressure correction method according to claim 13, wherein b (h) = b ₁ h.
Here, b ₁ is a correction coefficient for the height difference h. The blood pressure correction method according to any one of claims 12 to 15 , wherein a part of the subject is the outer ear and / or the periphery thereof. 16. The blood pressure correction method according to claim 12 , wherein a part of the subject is an external auditory canal and / or an auricle. The blood pressure correction method according to any one of claims 12 to 15 , wherein a part of the subject is a tragus and / or its periphery. For measuring the blood pressure value by pressing a portion of an artery of a subject, a measurement start pressure value pressure or to start decompression of the pressure compressing the pre Symbol subject, the detected posture of the subject was Measurement start pressure correction method based on correction. The subject of the posture, the is at or midline of the subject is either a vertical horizontal,
Wherein in the correction of the measurement start pressure value, before Symbol calculates a correction measurement start pressure value by subtracting a preset hydrostatic pressure correction value from the measurement start pressure value when the midline of the patient is vertical, before 20. The measurement start pressure correction method according to claim 19, wherein the measurement start pressure value is used as a corrected measurement start pressure value when the midline of the subject is horizontal. The subject of the attitude, said the slope angle between the midline and the vertical line of the object,
In the correction of the measurement start pressure value, the distance between the subject's heart measured in advance and a part of the subject and the inclination angle between the midline and the vertical line of the subject are measured with respect to the distance. Calculate the ratio of the height difference between the heart and a part of the subject, and subtract the product of a preset hydrostatic pressure correction value and the ratio of the height difference from the measurement start pressure value to obtain a corrected measurement start pressure value The measurement start pressure correction method according to claim 19, wherein:
The measurement start pressure correction method according to any one of claims 19 to 21 , wherein a part of the subject is the outer ear and / or the periphery thereof. The measurement start pressure correction method according to any one of claims 19 to 21 , wherein a part of the subject is an external auditory canal and / or an auricle. The measurement start pressure correction method according to any one of claims 19 to 21 , wherein a part of the subject is a tragus and / or its periphery.

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