JP5853132B2 - Biological information measuring device - Google Patents

Description

  The present invention relates to a biological information measurement apparatus that performs calculations related to biological information using biological measurement values of the trunk.

  The living body information measuring device of patent documents 1 measures the body fat percentage as living body information using living body impedance. This measuring apparatus measures the bioimpedance by bringing two casing parts having a current electrode and a voltage electrode into contact with each other at positions symmetrical to each other with respect to the navel in the trunk.

JP 2001-190513 A

  In the above-described biological information measuring device, the user brings the two casing portions into contact with the trunk. However, since the two housing parts are arranged visually, the two housing parts may be displaced from the correct positions. For this reason, the body fat percentage may not be calculated correctly.

  In addition, if this problem is a biological information measuring device that measures biological information using detection values of biological probes arranged at positions symmetrical to the reference position of the trunk, the biological information measuring device described above The same applies to other biological information measuring devices.

  In order to solve the above-described problems, an object of the present invention is to provide a biological information measuring device that can contribute to improvement of measurement accuracy of biological information.

The biological information measuring device of the present invention is the biological information measuring device, wherein the subcutaneous fat thickness at the first measurement position of the trunk is compared with the subcutaneous fat thickness at the second measurement position of the trunk, and the trunk reference And determining means for determining a symmetrical relationship between the first measurement position and the second measurement position with respect to a position.

  -In above-mentioned living body information measuring device, it is preferred that the standard position of the trunk is a predetermined position on the midline of the front of the trunk, or a predetermined position on the midline of the back of the trunk.

  In the biological information measuring device, the biological information measuring device includes a subcutaneous fat thickness measuring unit that measures the subcutaneous fat thickness, and a biological probe that measures biological information different from the subcutaneous fat thickness, The subcutaneous fat thickness measurement unit is preferably connected to the biological probe.

  In the above biological information measuring device, the biological information measuring device has a first biological probe and a second biological probe as the biological probe, and the first subcutaneous fat thickness measuring unit and the subcutaneous fat thickness measuring unit, A second subcutaneous fat thickness measurement unit; the first subcutaneous fat thickness measurement unit is connected to the first biological probe; and the second subcutaneous fat thickness measurement unit is connected to the second biological probe. Is preferred.

  In the biological information measuring device, the first biological probe and the second biological probe with respect to the reference position of the trunk by comparing the subcutaneous fat thickness at the first measurement position and the subcutaneous fat thickness at the second measurement position It is preferable to detect the positional deviation.

-In above-mentioned living body information measuring device, it is preferred that the 1st living body probe and the 2nd living body probe are electrodes which measure living body impedance.
-In the above-mentioned living body information measuring device, it is preferred that the living body probe is an ultrasonic probe.

-In the above-mentioned living body information measuring device, it is preferred that the living body information measuring device has a support part holding the living body probe and the subcutaneous fat thickness measuring unit.
-In the above-mentioned living body information measuring device, it is preferred that the subcutaneous fat thickness measurement unit and the living body probe have a structure which can be attached to and detached from each other.

  -In the above-mentioned living body information measuring device, it is preferred that the living body information measuring device measures at least one of living body composition information, living tissue structure information, myoelectric information, hemodynamics, and skin temperature.

  -In the above-mentioned living body information measuring device, it is preferred that the living body information measuring device reports the result of judgment of the symmetrical relation of the 1st measuring position and the 2nd measuring position with respect to the standard position of the trunk.

  The present invention provides a biological information measuring device that can contribute to improving the measurement accuracy of biological information.

The block diagram which shows the electrical constitution about the biological information measuring device of one embodiment of the present invention. The perspective view which shows the perspective structure about the biological information measuring device of embodiment. The top view which shows a state when it winds around the abdomen about the measurement part of embodiment. Sectional drawing which shows the cross-sectional structure of a umbilical-section about the abdomen of the user of a general body shape. The front view which shows the positional relationship of the trunk | drum with the 1st subcutaneous fat thickness measurement unit and the 2nd subcutaneous fat thickness measurement unit when it winds around the abdomen about the measurement part of embodiment. The flowchart which shows the procedure of the "visceral fat measurement control" performed by the control part of embodiment. The top view which shows the planar structure about the biometric information measuring apparatus of a modification. The top view which shows the planar structure about the biometric information measuring apparatus of a modification. The top view which shows the planar structure about the biometric information measuring apparatus of a modification. The top view which shows the planar structure about the biometric information measuring apparatus of a modification. The top view which shows the planar structure about the biometric information measuring apparatus of a modification. The top view which shows the planar structure about the biometric information measuring apparatus of a modification.

With reference to FIG. 1, the structure of the biological information measuring device 1 will be described.
The biological information measuring device 1 includes a main body 10 and a measuring unit 20. Moreover, visceral fat is measured as biological information. Visceral fat corresponds to “biological composition information” and “biological information”. In the measurement of visceral fat, at least one of the visceral fat amount and the visceral fat volume is calculated.

  The main body 10 includes an operation unit 12 used for inputting information necessary for measuring visceral fat, a display unit 13 for presenting various types of information to the user, and a control unit 11 for performing various calculations. In addition, a cable 14 for connecting the main body 10 and the measurement unit 20 is provided. The information input by the operation unit 12 includes the user's height, weight, waist circumference, age, gender, and the like.

  The measurement unit 20 includes an impedance measurement unit 40, a first subcutaneous fat thickness measurement unit 50, and a second subcutaneous fat thickness measurement unit 60. In addition, the belt 30 holds the impedance measurement unit 40, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60. The belt 30 corresponds to a “support portion”. The first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 correspond to a “subcutaneous fat thickness measurement unit”.

  The impedance measurement unit 40 includes a first current electrode 41, a second current electrode 42, a first voltage electrode 43, and a second voltage electrode 44. The first current electrode 41 and the second current electrode 42 constitute a current electrode pair. The first voltage electrode 43 and the second voltage electrode 44 constitute a voltage electrode pair. The first current electrode 41 and the second current electrode 42 apply a current to the living body. The first voltage electrode 43 and the second voltage electrode 44 detect a voltage between the first voltage electrode 43 and the second voltage electrode 44. In addition, as an electrode material, what carried out the metal plating process of the SUS and the resin material surface is used. The first current electrode 41 and the first voltage electrode 43 correspond to a “first biological probe”. When the first current electrode 41 corresponds to a first biological probe, the second current electrode 42 corresponds to a “second biological probe”. When the first voltage electrode 43 corresponds to a first biological probe, the second voltage electrode 44 corresponds to a “second biological probe”.

The configuration of the first subcutaneous fat thickness measurement unit 50 will be described.
The subcutaneous fat thickness measurement unit 50 includes two light emitting units 51 that irradiate near infrared light and one light receiving unit 52 that receives near infrared light. The two light emitting units 51 and the light receiving unit 52 are arranged in the height direction in the order of the light emitting unit 51, the light emitting unit 51, and the light receiving unit 52. The distance between the light emitting unit 51 and the light receiving unit 52 is preferably between about half and twice the general subcutaneous fat thickness at the position where the first subcutaneous fat thickness measurement unit 50 is arranged in the user's abdomen. .

The configuration of the second subcutaneous fat thickness measurement unit 60 will be described.
The subcutaneous fat thickness measurement unit 60 includes two light emitting units 61 that irradiate near infrared light and one light receiving unit 62 that receives near infrared light. The two light emitting units 61 and the light receiving unit 62 are arranged in the height direction in the order of the light emitting unit 61, the light emitting unit 61, and the light receiving unit 62. The distance between the light emitting unit 61 and the light receiving unit 62 is preferably between about half and twice the general subcutaneous fat thickness at the position where the second subcutaneous fat thickness measurement unit 60 is disposed in the user's abdomen. .

  The control unit 11 of the main body 10 includes a first current electrode 41, a second current electrode 42, a first voltage electrode 43, a second voltage electrode 44, a first subcutaneous fat thickness measurement unit 50, and a second subcutaneous fat. Signals are transmitted to and received from the thickness measurement unit 60.

The structure of the biological information measuring device 1 will be described with reference to FIG.
The belt 30 includes a connecting portion 31 that connects both ends of the belt 30 to each other, and a spine marking portion 33 that is fixed at a position facing the connecting portion 31 in the circumferential direction of the belt 30. The connection part 31 has the umbilical mark part 32 printed on the surface. The belt 30 is formed of a member having elasticity. The belt 30 is preferably in the most contracted state and the length of the belt 30 is smaller than the user's waist circumference. For this reason, for example, a material is used in which the length of the belt 30 is 50 cm in the most contracted state and the length of the belt 30 can be extended to 150 cm. As this material, for example, a cloth containing rubber can be cited.

  The first voltage electrode 43 and the second voltage electrode 44 are arranged on the belt 30 symmetrically with respect to the umbilical mark portion 32 of the connecting portion 31. Specifically, the distance from the first voltage electrode 43 to the umbilical mark portion 32 is equal to the distance from the second voltage electrode 44 to the umbilical mark portion 32.

  The first current electrode 41 and the second current electrode 42 are symmetrically disposed on the belt 30 with respect to the umbilical mark portion 32 of the connecting portion 31. Specifically, the distance from the first current electrode 41 to the umbilical mark portion 32 is equal to the distance from the second current electrode 42 to the umbilical mark portion 32.

  The first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are disposed on the belt 30 symmetrically with respect to the umbilical mark portion 32 of the connecting portion 31. Specifically, the distance from the first subcutaneous fat thickness measurement unit 50 to the umbilical mark portion 32 is equal to the distance from the second subcutaneous fat thickness measurement unit 60 to the umbilical mark portion 32.

  The distance from the first voltage electrode 43 to the umbilical mark portion 32 is smaller than the distance from the first current electrode 41 to the umbilical mark portion 32. The distance from the second voltage electrode 44 to the umbilical mark portion 32 is smaller than the distance from the second current electrode 42 to the umbilical mark portion 32.

  The first current electrode 41, the second current electrode 42, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60 are connected to each other via the belt 30. Further, when the belt 30 extends, the relative positions of the first current electrode 41, the second current electrode 42, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60 do not change.

  With reference to FIG. 3, the positional relationship of the measurement part 20 when the belt 30 is wound around a user is demonstrated. In addition, FIG.3 (b) has shown the measurement part 20 when wound around the user of the abdominal circumference larger than Fig.3 (a).

The connecting portion 31, the spine marking portion 33, the electrodes 41 to 44, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60 of the measurement unit 20 are fixed to the belt 30. For this reason, when the spine mark 33 is disposed at a position corresponding to the spine 112 and the umbilicus mark 32 is disposed at a correct position (hereinafter, “normal position”) corresponding to the navel 111, the measurement unit 20 In the abdomen 110 of the user 3 (a) and the abdomen 110 of the user in FIG.
The spine mark portion 33 is located at a position corresponding to the spine 112.
The connecting part 31 is located at a position corresponding to the umbilicus 111.
The first current electrode 41 is located near the right flank 113 and ahead of the right flank.
The second current electrode 42 is positioned near the left flank 114 and ahead of the left flank.
The first voltage electrode 43 is located near the umbilicus 111 and to the right of the umbilicus 111.
The second voltage electrode 44 is located near the umbilicus 111 and to the left of the umbilicus 111.
The first subcutaneous fat thickness measurement unit 50 is located between the umbilicus 111 and the right flank 113.
The second subcutaneous fat thickness measurement unit 60 is located between the umbilicus 111 and the left flank 114.

  The position of the trunk 100 to which the first subcutaneous fat thickness measurement unit 50 corresponds corresponds to the “first measurement position”. The position of the trunk 100 to which the second subcutaneous fat thickness measurement unit 60 corresponds corresponds to the “second measurement position”.

  Here, the belt 30 is wound around the abdomen 110 by visual observation of the user. For this reason, there exists a possibility that the position of the measurement part 20 may shift | deviate from a regular position. In addition, when the belt 30 is caught on the surface of the abdomen 110 and the extension amount of a part of the belt 30 is different from the extension amount of the other part, a part of the measurement unit 20 may be shifted from the normal position. If the bioelectrical impedance is measured in a state where the measurement unit 20 is deviated from the normal position, the calculation accuracy may be reduced. Therefore, the biological information measuring apparatus 1 determines whether or not the position of the measurement unit 20 is in the normal position using the subcutaneous fat thickness.

  The body composition structure of the trunk 100 will be described with reference to FIG. FIG. 4 shows a cross section of the umbilicus that is orthogonal to the frontal plane and passes through the umbilicus 111 in a user having a general body shape. Note that the position of the umbilicus 111 corresponds to the “trunk reference position”.

  The body fat 120 has subcutaneous fat 121 and visceral fat 122. The subcutaneous fat thickness is thinnest at the position of the spine 112. Further, in the front, it is thinnest at the position of the right thin portion 115 near the right flank 113 and in front of the right flank 113 and the left thin portion 116 near the left flank 114 and in front of the left flank 114. The position of the right flank 113 and the position of the left flank 114 are symmetrical with respect to the umbilicus 111. Further, the position of the right thin portion 115 and the position of the left thin portion 116 are in a bilaterally symmetrical relationship with respect to the umbilicus 111.

  The subcutaneous fat 121 becomes thinner from the umbilicus 111 toward the right thin portion 115. Further, the thickness slightly increases from the right thin portion 115 toward the right flank 113. Further, the thickness decreases from the umbilicus 111 toward the left thin portion 116. Further, the thickness slightly increases from the left thin portion 116 toward the left flank 114. Further, between the spine 112 and the right flank 113, the middle part of the spine 112 and the right flank 113 is the thickest, and the vicinity of the spine 112 is the thinnest. Further, between the spine 112 and the left flank 114, the middle part of the spine 112 and the right flank 113 is the thickest. Thus, the subcutaneous fat thickness has a symmetrical shape with respect to the umbilicus 111 and the spine 112. Although not shown, the subcutaneous fat 121 has a symmetrical shape with respect to a point on the midline C1 passing through the umbilicus 111 or the spine 112 in a cross section parallel to the umbilical section of the trunk 100.

The relationship between the positions of the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 and the subcutaneous fat thickness will be described with reference to FIG.
Since the subcutaneous fat thickness has a symmetrical shape with respect to the umbilicus 111 and the spine 112, the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are arranged symmetrically with respect to the umbilicus 111. The difference between the first subcutaneous fat thickness measured by the first subcutaneous fat thickness measurement unit 50 and the first subcutaneous fat thickness measured by the second subcutaneous fat thickness measurement unit 60 (hereinafter referred to as “subcutaneous fat thickness”). The difference TX ") is relatively small. On the other hand, when the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are not arranged symmetrically with respect to the umbilicus 111, the subcutaneous fat thickness difference TX is relatively large.

  As shown in FIG. 5 (a), the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are located on the umbilical section and from the umbilicus 111 to the distance from the first subcutaneous fat thickness measurement unit 50 (hereinafter referred to as the first subcutaneous fat thickness measurement unit 50). , “First distance L 1”) and the distance from the umbilicus 111 to the second subcutaneous fat thickness measurement unit 60 (hereinafter, “second distance L 2”), that is, a position symmetrical to the umbilicus 111. Sometimes the subcutaneous fat thickness difference TX is relatively small.

  As shown in FIG. 5B, when the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are on the umbilical section and the first distance L1 and the second distance L2 are different, the subcutaneous fat The thickness difference TX is relatively large.

  As shown in FIG. 5C, the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are different from the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 in height. When the first distance L1 and the second distance L2 coincide with each other, the subcutaneous fat thickness difference TX is relatively large. In general, since the vertical change in the subcutaneous fat thickness is smaller than the change in the circumferential direction, the subcutaneous fat thickness difference TX in the state of FIG. 5C is the subcutaneous fat in the state of FIG. 5B. It is smaller than the thickness difference TX.

With reference to FIG. 6, the visceral fat measurement control performed by the control unit 11 will be described.
This control is executed by the control unit 11 at predetermined intervals. That is, after the processing of the last step is finished, the execution of the control is suspended until the predetermined cycle elapses, and again after the predetermined cycle elapses. Visceral fat measurement control is executed from the first step.

  In step S11, when it is determined that the measurement button of the operation unit 12 is pressed, the process proceeds to step S12, and the first subcutaneous fat thickness and the second subcutaneous fat thickness are measured. Specifically, near-infrared light is irradiated from the light emitting unit 51 of the first subcutaneous fat thickness measurement unit 50. And the light quantity of the near infrared light which passed the biological body by the light-receiving part 52 is measured. Based on this light quantity, the first subcutaneous fat thickness of the part corresponding to the first subcutaneous fat thickness measurement unit 50 is calculated. Moreover, near infrared light is irradiated from the light emission part 61 of the 2nd subcutaneous fat thickness measurement unit 60. FIG. And the light quantity of the near infrared light which passed the biological body by the light-receiving part 62 is measured. Based on this light quantity, the second subcutaneous fat thickness of the part corresponding to the second subcutaneous fat thickness measurement unit 60 is calculated.

  In step S13, it is determined whether or not the subcutaneous fat thickness difference TX is within a predetermined range. When it is determined in step S13 that the subcutaneous fat thickness difference TX is outside the predetermined range, the process proceeds to step S16, and the display unit 13 displays that there is a possibility that the position of the measurement unit 20 is shifted.

  On the other hand, when the subcutaneous fat thickness difference TX is within the predetermined range, the process proceeds to step S14, and the bioelectrical impedance is measured. Specifically, supply of current to the first current electrode 41 and the second current electrode 42 is started. Then, the voltage value is measured by the first voltage electrode 43 and the second voltage electrode 44.

  In step S <b> 14, visceral fat is calculated based on the voltage value calculated in step S <b> 13, the first subcutaneous fat thickness, the second subcutaneous fat thickness, and various information input via the operation unit 12. Then, the calculation result of the visceral fat is displayed on the display unit 13.

The biological information measuring device 1 of the present embodiment has the following effects.
(1) The biological information measuring apparatus 1 compares the first subcutaneous fat thickness and the second subcutaneous fat thickness, and thereby compares the measurement position of the first subcutaneous fat thickness measurement unit 50 with respect to the position of the navel 111 of the trunk 100 and the second subcutaneous fat thickness. The symmetry relationship between the measurement positions of the fat thickness measurement unit 60 is determined.

  According to this configuration, the biological information measuring apparatus 1 is configured such that the measurement position of the first subcutaneous fat thickness measurement unit 50 and the measurement position of the second subcutaneous fat thickness measurement unit 60 are in a symmetrical position, that is, the measurement unit 20 It can be determined whether or not it is arranged at the normal position. For this reason, since the frequency where the measurement part 20 is not arrange | positioned in a regular position becomes low, it can contribute to the improvement of the measurement precision of a visceral fat.

  (2) The first current electrode 41, the second current electrode 42, the first voltage electrode 43, the second voltage electrode 44, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60 are connected via a belt. Connected to each other. The first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are arranged symmetrically with respect to the umbilical mark portion 32.

  According to this configuration, since all members of the impedance measuring unit 40 are connected to the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 via the belt 30, the first current electrode 41 and The left-right symmetrical relationship of the second current electrode 42 and the left-right symmetrical relationship of the first voltage electrode 43 and the second voltage electrode 44 can be determined by one subcutaneous fat thickness difference TX.

  (3) The biological information measuring apparatus 1 includes the belt 30 that supports the impedance measuring unit 40, the first subcutaneous fat thickness measuring unit 50, and the second subcutaneous fat thickness measuring unit 60. According to this configuration, the user causes the impedance measurement unit 40, the first subcutaneous fat thickness measurement unit 50, and the second subcutaneous fat thickness measurement unit 60 to contact the trunk 100 by winding the belt 30 around the abdomen 110. be able to. For this reason, it can measure easily compared with the biological information measuring device 1 which does not have the belt 30.

  (4) When the subcutaneous fat thickness difference TX is outside the predetermined range, the biological information measuring apparatus 1 notifies the display unit 13 that the position of the measurement unit 20 is deviated from the normal position. According to this configuration, it is possible to prompt the user to set the position of the measurement unit 20 to the normal position. For this reason, it can contribute to the improvement of the measurement accuracy of visceral fat.

  (5) The belt 30 has an umbilicus mark portion 32 and a spine mark portion 33. According to this configuration, when the user winds the belt 30 around the abdomen 110, the user can mark the umbilicus mark 32 and the spine mark 33. Thereby, it is easy to align the position of the measurement unit 20 with the normal position.

  (6) The biological information measuring apparatus 1 calculates the visceral fat using the subcutaneous fat thickness measured by the subcutaneous fat thickness measuring units 50 and 60. According to this configuration, the measurement accuracy of visceral fat is improved.

  The present invention includes embodiments other than the above-described embodiment. Hereinafter, the modification of the said embodiment as other embodiment of this invention is shown. The following modifications can be combined with each other.

  The measurement unit 20 according to the embodiment includes the umbilical mark portion 32 and the spine mark portion 33 on the belt 30. On the other hand, in the measurement unit 20 of the modified example, at least one of the umbilical mark part 32 and the spine mark part 33 is omitted.

  The measurement unit 20 according to the embodiment arranges the first current electrode 41 and the second current electrode 42 on the belt 30 at positions corresponding to the front side of the trunk 100. On the other hand, the measurement unit 20 according to the modified example arranges the first current electrode 41 and the second current electrode 42 on the belt 30 at positions corresponding to the back side of the trunk 100.

  The measurement unit 20 of the embodiment arranges the first voltage electrode 43 and the second voltage electrode 44 on the belt 30 at positions corresponding to the front side of the trunk 100. On the other hand, the measurement unit 20 according to the modified example arranges the first voltage electrode 43 and the second voltage electrode 44 on the belt 30 at positions corresponding to the back side of the trunk 100.

  The measurement unit 20 of the embodiment arranges the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 on the belt 30 at positions corresponding to the front side of the trunk 100. On the other hand, the measurement unit 20 of the modified example arranges the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 on the belt 30 at positions corresponding to the back side of the trunk 100.

-Belt 30 of an embodiment is wound around an umbilical section. On the other hand, the belt 30 of the modified example is wound around a section above the umbilical section or a section below the umbilical section.
The biological information measuring apparatus 1 according to the embodiment includes a separate main body 10 and a belt 30. On the other hand, as shown in FIG. 7, the biological information measuring apparatus 1 according to the modification includes an integrated main body 10 and a support body 80. The support 80 has a right side portion 81 corresponding to the umbilicus 111 to the right flank 113 and a left side portion 82 corresponding to the umbilicus 111 to the left flank 114. The first current electrode 41 is connected to the right end of the right portion 81. The second current electrode 42 is connected to the left end of the left portion 82. The first voltage electrode 43 is fixed to the end surface of the main body 70 on the abdomen 110 side. The second voltage electrode 44 is fixed to the end surface of the main body 70 on the abdomen 110 side and on the left side of the first voltage electrode 43. The first subcutaneous fat thickness measurement unit 50 is connected to the left end of the right portion 81. The second subcutaneous fat thickness measurement unit 60 is connected to the right end of the left portion 82.

  The biological information measuring device 1 of the above embodiment has a belt 30. On the other hand, as shown in FIG. 8, the biological information measuring apparatus 1 according to the modified example omits the belt 30. In this modification, each electrode 41 to 44 is attached to the trunk 100. The first subcutaneous fat thickness measurement unit 50 is connected to the first voltage electrode 43. The second subcutaneous fat thickness measurement unit 60 is connected to the second voltage electrode 44. In this modified example, the first voltage electrode 43 and the second voltage electrode 44 can be prevented from being arranged symmetrically with respect to the navel 111. In this modification, the first voltage electrode 43 corresponds to a “first biological probe”, and the second voltage electrode 44 corresponds to a “second biological probe”. This modification is referred to as Modification X.

  In the modified example X, as shown in FIG. 9, the first voltage electrode 43 and the first subcutaneous fat thickness measuring unit 50 are connected via the connecting rod 91, and the second voltage electrode 44 and the second subcutaneous fat are connected. The thickness measuring unit 60 can also be connected via the connecting rod 91.

  The biological information measuring device 1 of the above embodiment has a belt 30. On the other hand, as shown in FIG. 10, the biological information measuring apparatus 1 according to the modified example omits the belt 30. In this modified example, in this modified example, the electrodes 41 to 44 are attached to the trunk 100. The first subcutaneous fat thickness measurement unit 50 is connected to the first current electrode 41. The second subcutaneous fat thickness measurement unit 60 is connected to the second current electrode 42. In this modified example, it is possible to suppress the first current electrode 41 and the second current electrode 42 from being arranged symmetrically with respect to the navel 111. In this modification, the first current electrode 41 corresponds to a “first biological probe”, and the second current electrode 42 corresponds to a “second biological probe”. This modification is referred to as Modification Y.

  In the above modification Y, as shown in FIG. 11, the first current electrode 41 and the first subcutaneous fat thickness measurement unit 50 are connected via the connecting rod 91, and the second current electrode 42 and the second subcutaneous fat are connected. The thickness measuring unit 60 can also be connected via the connecting rod 91.

  In the modified example X and the modified example Y, the electrodes 41 to 44 and the subcutaneous fat thickness measuring units 50 and 60 can be attached to and detached from the electrodes 41 to 44 and the subcutaneous fat thickness measuring units 50 and 60, respectively. You can also. In this case, after measuring the first subcutaneous fat thickness and the second subcutaneous fat thickness in the state of FIG. 8 and calculating the subcutaneous fat thickness difference TX, the first subcutaneous fat thickness and the second subcutaneous fat thickness are calculated in the state of FIG. Measurement can be made to calculate the subcutaneous fat thickness difference TX.

  The first subcutaneous fat thickness measurement unit 50 of the embodiment is disposed between the umbilicus 111 and the right thin portion 115 when the measurement unit 20 is in the normal position, and the second subcutaneous fat thickness measurement unit 60 is configured such that the measurement unit 20 When in the normal position, it is placed between the umbilicus 111 and the left thin section 116. On the other hand, the first subcutaneous fat thickness measurement unit 50 of the modified example is disposed at a position corresponding to the right thin portion 115 when the measurement unit 20 is in the normal position, and the second subcutaneous fat thickness measurement unit 60 includes the measurement unit 20. When in the normal position, it is arranged at a position corresponding to the space between the left thin portions 116. That is, the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are arranged at the thinnest subcutaneous fat thickness on the front side of a general body type user. For this reason, when the position of the measurement unit 20 deviates from the normal position, there is a high possibility that the change in the subcutaneous fat thickness difference TX becomes large. Thereby, the determination precision of whether the position of the measurement part 20 has shifted | deviated from the normal position increases.

  The biological information measuring apparatus 1 according to the embodiment connects the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 to the belt 30. On the other hand, the biological information measuring apparatus 1 of the modified example has a structure in which the first subcutaneous fat thickness measuring unit 50 and the second subcutaneous fat thickness measuring unit 60 can be attached to and detached from the belt 30. This modification is referred to as Modification Z.

  In the modified example Z, one of the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 can be omitted. In this case, the first subcutaneous fat thickness measurement unit 50 is attached to the attachment position of the first subcutaneous fat thickness measurement unit 50 of the belt 30 to measure the first subcutaneous fat thickness measurement unit, and the first subcutaneous fat thickness measurement unit 50 is attached to the belt 30. The second subcutaneous fat thickness measurement unit 60 is attached to the attachment position of the second subcutaneous fat thickness measurement unit 60 to measure the second subcutaneous fat thickness measurement unit.

  The measurement unit 20 of the embodiment has a first subcutaneous fat thickness measurement unit 50 and a second subcutaneous fat thickness measurement unit 60. On the other hand, the measurement unit 20 of the modification has a first subcutaneous fat thickness measurement unit 50 and a second subcutaneous fat thickness measurement unit 60 that measure the subcutaneous fat thickness due to bioelectrical impedance. In this case, the distance between the electrodes constituting the voltage electrode pair is about half to twice the general subcutaneous fat thickness at the position where the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60 are arranged. Between.

  The biological information measuring device 1 according to the embodiment includes an impedance measuring unit 40. On the other hand, the biological information measuring device 1 of the modified example has an ultrasonic measurement unit. The ultrasonic measurement unit has an ultrasonic transmitter and an ultrasonic receiver. In this modification, one of the ultrasonic transmitter and the ultrasonic receiver corresponds to the “first biological probe” and the “ultrasonic probe”, and the other of the ultrasonic transmitter and the ultrasonic receiver is the “first biological probe”. It corresponds to “2 biological probe” and “ultrasonic probe”. This modified example is referred to as “modified example W”.

  -In the said modification W, it can replace with an ultrasonic transmitter and an ultrasonic receiver, and can also employ | adopt the ultrasonic probe which serves as an ultrasonic transmitter and an ultrasonic receiver. In this case, the biological information measuring apparatus 1 can have only one ultrasonic probe and one subcutaneous fat measuring unit. In the configuration having only one ultrasonic probe and one subcutaneous fat measurement unit, the ultrasonic probe and the subcutaneous fat measurement unit have measurement blocks that are fixed to each other. The biological information measuring apparatus 1 measures the biological information in a state where the measurement block is arranged at the first measurement position on the right side of the umbilicus 111, and then places the measurement block on the second measurement position on the left side of the umbilicus 111. The biological information is measured in the arranged state. Then, by comparing the subcutaneous fat thickness at the first measurement position and the subcutaneous fat thickness at the second measurement position, the ultrasonic measurement result at the first measurement position and the ultrasonic measurement result at the second measurement position are It can be determined whether or not the result is symmetrical.

  The measurement unit 20 of the embodiment includes an impedance measurement unit 40, a first subcutaneous fat thickness measurement unit 50, and a second subcutaneous fat thickness measurement unit 60. On the other hand, as shown in FIG. 12, the measurement unit 20 of the modified example omits the first subcutaneous fat thickness measurement unit 50 and the second subcutaneous fat thickness measurement unit 60.

  The impedance measurement unit 40 of the measurement unit 20 of this modification includes a third voltage electrode 45, a fourth voltage electrode 46, a fifth voltage electrode 47, and a sixth voltage electrode 48 in addition to the electrodes 41 to 44. The third voltage electrode 45 and the fourth voltage electrode 46 are disposed between the first current electrode 41 and the first voltage electrode 43 on the belt 30. The fifth voltage electrode 47 and the sixth voltage electrode 48 are disposed between the second current electrode 42 and the second voltage electrode 44 on the belt 30. The first voltage electrode 43 and the second voltage electrode 44 have the function of current electrodes.

  When measuring the first subcutaneous fat thickness, the first current electrode 41 and the first voltage electrode 43 constitute a current electrode pair. At this time, the third voltage electrode 45 and the fourth voltage electrode 46 constitute a voltage electrode pair. The first subcutaneous fat thickness is calculated from the bioimpedance measured by the third voltage electrode 45 and the fourth voltage electrode 46. That is, the first current electrode 41, the first voltage electrode 43, the third voltage electrode 45, and the fourth voltage electrode 46 function as a “first subcutaneous fat thickness measurement unit”.

  When measuring the second subcutaneous fat thickness, the second current electrode 42 and the second voltage electrode 44 constitute a current electrode pair. At this time, the fifth voltage electrode 47 and the sixth voltage electrode 48 constitute a voltage electrode pair. The second subcutaneous fat thickness is calculated from the bioimpedance measured by the fifth voltage electrode 47 and the sixth voltage electrode 48. That is, the second current electrode 42, the second voltage electrode 44, the fifth voltage electrode 47, and the sixth voltage electrode 48 function as a “second subcutaneous fat thickness measurement unit”.

  The biological information measuring apparatus 1 of the embodiment proceeds to step S14 when the subcutaneous fat thickness difference TX is within the predetermined range in step S13 of visceral fat measurement control. On the other hand, the biological information measuring apparatus 1 of the modified example has been previously measured in the visceral fat measurement control, the subcutaneous fat thickness difference TX being within a predetermined range, and the first subcutaneous fat thickness and the second subcutaneous fat thickness measured this time. When the difference between the first subcutaneous fat thickness and the second subcutaneous fat thickness is small, the process proceeds to step S14. In general, subcutaneous fat is less likely to change than visceral fat. For this reason, by comparing the subcutaneous fat measured this time with the subcutaneous fat measured last time, it is possible to detect the displacement of the measurement unit 20 with respect to the trunk 100.

  The biological information measuring apparatus 1 of the embodiment measures visceral fat in a state where the belt 30 is wound around the abdomen 110 and fixed. On the other hand, the biological information measuring apparatus 1 according to the modification measures the visceral fat while winding the belt 30 around the abdomen 110 and moving the belt 30 in the circumferential direction.

  Specifically, the first subcutaneous fat thickness, the second subcutaneous fat thickness, and the bioelectrical impedance are measured every predetermined time, and the first subcutaneous fat thickness, the second subcutaneous fat thickness, The bioimpedance is stored in the control unit 11. The control unit 11 calculates visceral fat using the detection value of the set with the smallest subcutaneous fat thickness TX among the sets of the first subcutaneous fat thickness, the second subcutaneous fat thickness, and the bioelectrical impedance stored in the control unit 11. calculate. This modification is referred to as Modification V.

  In the modified example V, the subcutaneous fat thickness difference TX can be calculated every predetermined time while the belt 30 is wound around the abdomen 110 and the belt 30 is moved in the circumferential direction. In this case, it is also possible to display on the display unit 13 whether the subcutaneous fat thickness difference TX is outside the predetermined range or within the predetermined range, that is, whether the position of the belt 30 is deviated from the normal position.

  The biological information measuring device 1 according to the embodiment includes a measuring unit 20. On the other hand, the measurement unit 20 is omitted from the biological information measuring apparatus according to the modification. The biometric information measuring device of this modification is inputted with the first subcutaneous fat thickness and the second subcutaneous fat thickness measured by another measuring device, so that the first subcutaneous fat thickness measurement unit and the second subcutaneous fat at the time of measurement are input. It is determined whether or not the position of the thickness measurement unit is symmetrical with respect to the umbilicus 111.

  -The living body information measuring device 1 of an embodiment measures visceral fat as living body composition information. On the other hand, the biological information measuring device according to the modified example measures at least one of subcutaneous fat mass, muscle mass, and bone density as biological composition information. In this case, the measurement unit 20 has a biological probe corresponding to biological information to be measured.

  -The living body information measuring device 1 of an embodiment measures visceral fat as living body information. On the other hand, the biological information measuring apparatus according to the modification measures at least one of biological composition information, biological tissue structure information, myoelectric information, hemodynamics, and skin temperature as biological information. In any biological information, measurement accuracy can be improved by arranging the first biological probe and the second biological probe symmetrically with respect to the reference position on the midline C1. Further, when comparing biological information at symmetrical positions, the comparison accuracy can be improved. The biological tissue structure information includes biological cross-sectional image information.

  In this modification, the measurement unit 20 has a biological probe corresponding to biological information to be measured. In addition, as an example of a biological probe, in addition to an electrode for measuring biological impedance, a light emitting unit and a light receiving unit for measuring the amount of transmitted near infrared light, an ultrasonic transmitter and receiver, a laser transmitter and receiver, Examples include skin surface electrodes, needle electrodes, thermistors, and the like.

  DESCRIPTION OF SYMBOLS 1 ... Biological information measuring device, 30 ... Belt (support body), 41 ... 1st electric current electrode (biological probe, 1st biological probe), 42 ... 2nd electric current electrode (biological probe, 2nd biological probe), 43 ... 1st 1 voltage electrode (biological probe, first biological probe), 44 ... second voltage electrode (biological probe, second biological probe), 50 ... first subcutaneous fat thickness measuring unit, 60 ... second subcutaneous fat thickness measuring unit.

Claims (11)

In the biological information measuring device,
Comparing the subcutaneous fat thickness at the first measurement position of the trunk and the subcutaneous fat thickness at the second measurement position of the trunk;
A determination unit configured to determine a symmetric relationship between the first measurement position and the second measurement position with respect to a reference position of the trunk;
The biological information measuring device characterized by the above. The biological information measuring device according to claim 1, wherein the reference position of the trunk is a predetermined position on a midline in front of the trunk or a predetermined position on the midline on the back of the trunk. The biological information measuring device includes a subcutaneous fat thickness measurement unit that measures the subcutaneous fat thickness, and a biological probe that measures biological information different from the subcutaneous fat thickness,
The biological information measuring device according to claim 1, wherein the subcutaneous fat thickness measuring unit is connected to the biological probe. The biological information measuring device has a first biological probe and a second biological probe as the biological probe,
The subcutaneous fat thickness measurement unit has a first subcutaneous fat thickness measurement unit and a second subcutaneous fat thickness measurement unit,
The first subcutaneous fat thickness measurement unit is connected to the first living body probe;
The biological information measuring device according to claim 3, wherein the second subcutaneous fat thickness measuring unit is connected to the second biological probe. 5. The positional deviation between the first living body probe and the second living body probe with respect to the reference position of the trunk is detected by comparing the subcutaneous fat thickness at the first measuring position and the subcutaneous fat thickness at the second measuring position. The biological information measuring device according to 1. The biological information measuring device according to claim 4, wherein the first biological probe and the second biological probe are electrodes that measure biological impedance. The biological information measuring device according to claim 3, wherein the biological probe is an ultrasonic probe. The biological information measuring device according to any one of claims 3 to 7, wherein the biological information measuring device includes a support unit that holds the biological probe and the subcutaneous fat thickness measuring unit. The biological information measuring device according to any one of claims 3 to 8, wherein the subcutaneous fat thickness measurement unit and the biological probe have a structure that can be attached to and detached from each other. The biological information measuring device according to any one of claims 1 to 9, wherein the biological information measuring device measures at least one of biological composition information, biological tissue structure information, myoelectric information, hemodynamics, and skin temperature. . The biological information according to any one of claims 1 to 10, wherein the biological information measuring device notifies a result of determination of a symmetric relationship between the first measurement position and the second measurement position with respect to a reference position of the trunk. measuring device.