JP2019063156A - Biological sensor - Google Patents

Abstract

To provide a biological sensor whose detection accuracy is improved.SOLUTION: A biological sensor 1 comprises: a plate 20 having a curvature to be disposed along the surface of a living body H; and a pulse wave sensor 10 provided on the surface of the plate 20, the surface facing the living body H.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a biological sensor.

  As a sensor for detecting a biological signal of a living body, there is a sheet-like biological sensor provided with a piezoelectric sensor and a foam sheet laminated and integrated on one surface of the piezoelectric sensor (see, for example, Patent Document 1). By attaching this biological sensor, for example, to a position corresponding to the radial artery (wrist) of the living body, the pulse of the living body can be measured.

JP, 2014-147571, A

  When attaching a biological sensor to a living body, it is difficult to determine the mounting position of the biological sensor because the area of the radial artery to be measured is very narrow. In this case, it is conceivable to make the detection surface of the biological sensor wider than the radial width of the radial artery. Thereby, even if the position of the radial artery can not be accurately grasped, if the biological sensor is provided in the area where the radial artery is considered to be present, any region of the biological sensor overlaps the radial artery. It can be easily attached to the position of the radial artery.

  However, a portion of the detection surface of the biological sensor that is not in contact with the region corresponding to the radial artery does not receive vibration from the living body due to the pulse, and thus becomes a stray capacitance. That is, in the case where the biosensor is attached to be wound around the wrist, when only one point of the radial artery is elevated, the corresponding portion of the biosensor is pushed up and contracted in the thickness direction of the biosensor, while being elevated The area around the area does not receive the push-up force associated with the protuberance of the living body, and the contracted area is pushed up to expand in the thickness direction (the size of the thickness increases).

  Then, the sensor as a whole includes detection components from each of the contracted area and the expanded area, and in addition to the component due to the vibration from the living body, the change component other than the vibration (expanded in the thickness direction Detection component) is also included in the detection result. As a result, the vibration from the living body can not be accurately measured, and the detection accuracy may be lowered.

  The problem to be solved by the present invention is to provide a biological sensor with improved detection accuracy.

  In order to solve the above problems, one aspect of the present invention is a biological sensor for detecting a biological signal in a living body, the plate having a curvature disposed along the surface of the living body, and the living body in the plate And a sheet sensor provided on the side surface.

  According to the biological sensor of the present invention, detection accuracy can be improved.

It is a sectional view of a living body sensor. It is a top view of a living body sensor. It is a perspective view of a living body sensor. It is sectional drawing of the other example of a biometric sensor. It is a perspective view of the other example of a living body sensor.

  Hereinafter, embodiments of a biological sensor to which the present invention is applied will be described with reference to the drawings. In addition, in each embodiment, the same code | symbol may be attached | subjected about a common element, member, etc., and the description may be abbreviate | omitted or simplified. In addition, the ratio of thickness and dimension of each component is appropriately adjusted.

First Embodiment
A first embodiment of the present invention will be described. FIG. 1 is a cross-sectional view of the biological sensor according to the first embodiment. As shown in FIG. 1, the biosensor 1 according to the present embodiment is used by being attached to a part of a human body that is a living body. The pulse wave sensor 10 constituting the living body sensor 1 has a flat shape, and is attached, for example, at a position corresponding to a radial artery on the wrist of the human body. At this time, the pulse wave sensor 10 detects the vibration of the radial artery (a living body vibration generated from a living body) as a biological signal.

  The biological sensor 1 includes a pulse wave sensor 10 and a plate 20. The pulse wave sensor 10 is a piezoelectric sensor that converts vibration (pressure) such as a pulse wave into a voltage. The shape of the pulse wave sensor 10 may be arbitrary, but in the present embodiment, it is formed in a film shape or a sheet shape. The pulse wave sensor 10 is preferably flexible. The material used for the pulse wave sensor 10 may be, for example, an inorganic material such as zinc zirconate titanate, but in the case of using an inorganic material, even if it is divided so as to be able to be arranged along the plate 20 Good. The piezoelectric material used for the pulse wave sensor 3 in the present embodiment is a flexible polymer material. The polymeric material used for pulse wave sensor 10 may be, for example, any of polyvinylidene fluoride (PVDF), polypropylene (PP) and the like. The pulse wave sensor 10 can be set, for example, to a width dimension of about 1⁄5 of the length around the wrist of the human body.

  As pulse wave sensor 10, an electret sensor is used as an example. The electret sensor as the pulse wave sensor 10 includes a pair of electrodes 12 widely covering the base material on both sides of the sheet-like base material 11, and is charged. The electret sensor has a property that the charge increases (is generated) as the thickness dimension decreases (contracts), and the charge decreases (disappears) as the thickness dimension increases (expansion). The pulse wave sensor 10 detects the displacement in the thickness direction (contraction direction). The pulse wave sensor 10 does not expand or contract in the surface direction. The electret sensor detects the pressure in the thickness direction by forming a porous material including a large number of flat pores.

  The plate 20 is made of, for example, a resin, is made of a plastic material that is harder than the pulse wave sensor 10, is harder than the pulse wave sensor 10, and has a large elastic modulus. The plate 20 may be made of other materials such as metal and nonmetal. The plate 20 is flat and substantially rectangular as shown in FIG. The plate 20 is, as shown in FIG. 1, provided with a concave portion having a curvature disposed along the surface of the wrist of the human body, for example, a part of a hollow hollow cylinder of uniform thickness in the axial direction It has a tunnel-like shape (hereinafter referred to as “arch shape”) in which the shape is not changed in the depth direction. The curvature of the plate 20 may be the same as the curvature of the surface of the living body, but it does not have to be the same, as long as the curvature is close to the curvature of the surface of the living body.

  Also, the plate 20 has, for example, a width that is greater than the width of the pulse wave sensor 10. The plate 20 is mounted in a state of being pressed against the wrist of the living body H by the adhesive sheet 40, as shown in FIG. For this reason, the arch-shaped outer ends of the plate 20 are respectively disposed on the side of the wrist corresponding to the radial artery in the wrist of the human body and pressed against the wrist. The plate 20 may be made of, for example, an adhesive sheet such as a bandage, or may be mounted in a state where the arched outer end of the plate 20 is pressed against the wrist of the living body H by a cuff, a band or the like. .

  The pulse wave sensor 10 is disposed on the concave surface of the plate 20 so as to include a position corresponding to the radial artery on the wrist of the human body. The width dimension of the pulse wave sensor 10 is set to be shorter than the width dimension of the plate 20, that is, shorter than the distance between the outer ends of the plate 20, as shown in FIGS. It protrudes outside the end of the pulse wave sensor 10 in the planar direction. The width dimension width of the pulse wave sensor 10 may be the same as the width dimension of the plate 20, and both end portions of the pulse wave sensor 10 may be disposed so as to coincide with the outer end portions of the plate 20.

  In the biological sensor 1 according to the present embodiment, the pulse wave sensor 10 detects the vibration of the radial artery caused by the vibration in the radial artery. For example, as shown by a dotted line in FIG. 1 by the pulse wave in the radial artery, when the skin S of the body swells, the pulse wave sensor 10 is pressed and contracted while swelling. In the pulse wave sensor 10, the vibration of the radial artery is detected by the change in volume based on the contraction and the expansion, so the vibration of the radial artery is detected by the pulse wave sensor 10 contracting or expanding.

  Here, assuming that the pulse wave sensor 10 is simply mounted on the skin S without providing the plate 20, the area around the portion contracted while swelling due to the vibration of the radial artery in the pulse wave sensor 10 is conversely expanded. Will occur. As a result, in the pulse wave sensor 10, a contracted portion and an expanded portion are generated, and components other than the radial artery vibration are also included in the detection component, and the detection accuracy by the pulse wave sensor 10 is lowered.

  On the other hand, in the biosensor 1 according to the present embodiment, the pulse wave sensor 10 is provided on the surface of the living body H on the plate 20 having a curvature disposed along the surface of the living body H. The plate 20 has a curvature disposed along the surface of the living body H and is made of a plastic material, and each of the arch-shaped outer ends corresponds to the radial artery in the wrist of the human body. It is placed laterally and pressed against the wrist.

  For this reason, even when pressure is received from the living body H side by the swelling of the skin S, the pulse wave sensor 10 in the biological sensor 1 contracts while the swelling is suppressed by the plate 20. Since the rise of the pulse wave sensor 10 is suppressed by the plate 20, the expansion around the contracted portion in the pulse wave sensor 10 is suppressed. As a result, the pulse wave sensor 10 can suppress the detection of components other than the vibration of the living body, so that the detection accuracy of the vibration from the living body can be improved.

  Furthermore, since the plate 20 is provided, the biosensor 1 moves in the thickness direction as a whole (the thickness of the biosensor 1 does not change but the entire biosensor 1 floats away from the surface of the living body). You can suppress that. Therefore, it can contribute to the improvement of detection accuracy of the vibration by living body sensor 1.

  In addition, a plate 20 is provided, and by pressing both ends of the arch shape in the plate 20 against the wrist of the living body H, force in the thickness direction applied from the external environment of the living body, for example, pressurization with a cuff Even if the pressure at the time of contact or any object strikes the biosensor 1 from the outside of the plate 20, the outer end of the plate 20 abuts the living body at both ends, and the plate 20 is not deformed. Therefore, the force from the outside of the plate 20 is not transmitted to the inside. Thereby, it is possible to detect the vibration of the living body without being influenced by the external environment of the biosensor 1 (force from the outside).

Second Embodiment
Next, a second embodiment of the present invention will be described. FIG. 4 is a cross-sectional view of the biosensor according to the second embodiment. As shown in FIG. 4, the biological sensor 2 according to the present embodiment includes the pulse wave sensor 10 and the plate 20 in the biological sensor 1 according to the first embodiment. Further, on the living body H side of the pulse wave sensor 10, an internal plate 30 is provided.

  The inner plate 30 is made of the same material as the plate 20. For this reason, the inner plate 30 is not deformed even if it receives pulse vibration. Also, the inner plate 30 is flat, and the width dimension of the inner plate 30 is smaller than the width dimension of the plate 20. For this reason, the inner plate 30 is disposed at a position sandwiched between the arched ends of the plate 20. The inner plate 30 is disposed at a position corresponding to the radial artery. For this reason, the inner plate 30 moves in the direction approaching the inner plate 30 and in the direction away from the inner plate 30 by the vibration of the radial artery.

  Thus, the biological sensor 2 in which the pulse wave sensor 10 is sandwiched between the plate 20 and the inner plate 30 is attached to the living body H. At that time, the outer end of the plate 20 is pressed against the wrist of the living body H by an adhesive such as a bandage, a cuff, a band or the like. The inner plate 30 may be made of a material having a smaller density than the plate 20.

  If the weight of the inner plate 30 is large, the inner plate 30 may act to stop the vibration of the surface of the living body due to the pulse, so it is desirable that the inner plate 30 be lightweight. In addition, the inner plate 30 may move while maintaining the tilt, or may move in a tilt direction.

  In the biological sensor 2 according to the second embodiment, the inner plate 30 is provided, so the skin S swells up due to the vibration of the radial artery, and the inner plate is even when the pulse wave sensor 10 receives pressure from the living body H side. As 30 moves, pressure can be widely applied to the lower surface of pulse wave sensor 10. Therefore, the pulse wave sensor 10 can be contracted over a wide area range. At this time, on the opposite side of the living body H in the pulse wave sensor 10, a plate 20 having a curvature disposed along the surface of the living body H is provided, whereby the pulse wave sensor 10 is suppressed from rising. While contracting. Since the rise of the pulse wave sensor 10 is suppressed by the plate 20, the pressure from the inner plate 30 can be efficiently detected by the pulse wave sensor 10. As a result, the pulse wave sensor 10 can contribute to improvement in detection accuracy by the biological sensor 1 by being sandwiched between the plate 20 and the internal plate 30.

  Further, when the surface of the living body H vibrates due to the pulse due to the provision of the internal plate 30, the distance between the internal plate 30 and the plate 20 becomes narrow, and the area of the portion displaced in the thickness direction of the biological sensor 1 is It becomes wider compared to the case where the inner plate 30 is not provided. Therefore, a uniform pressure distribution can be formed in the pulse wave sensor 10, and the detection accuracy can be enhanced, since the displacement due to the swelling of the skin S is widely averaged.

  As mentioned above, although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design changes and the like within the scope of the present invention are also included. .

  For example, in each of the above-described embodiments, even if the position at which the biosensors 1 and 2 are provided is a position other than the wrist in the human body, it may be attached to any portion as long as it is a target for detecting the vibration of the biological For example, the positions of the head, arms, ankles, legs, etc. of the human body may be used. Moreover, although only one of the biosensors 1 and 2 is provided on the wrist, a plurality of the biosensors 1 and 2 may be attached to the wrist and used. In this case, for example, by installing a plurality of biosensors 1 and 2 along the blood flow direction of the radial artery, it is possible to measure, for example, the pulse wave propagation velocity, and it becomes possible to grasp the blood vessel age. . The pulse wave sensor 10 may detect not only pulse waves but also body vibrations such as heartbeats and blood flow sounds.

  Moreover, in said each embodiment, although biometric sensor 1 and 2 is a tunnel-like shape (arch shape) which an arch-like or arc-like shape does not change in a depth direction, you may be another shape. For example, as shown in FIG. 5, the biosensor of another shape is constituted by a plate 50 having a dome shape and the pulse wave sensor 10. The plate 50 is provided with a flat plate portion 51 and a dome-shaped dome portion 52 provided on the center side of the flat plate portion 51 in the plane direction, and curved in a curved shape so that the central portion is raised. The dimensions in the thickness direction of the flat plate portion 51 and the dome portion 52 are both uniform, and in the dome portion 52, one surface is convex because the central portion is raised, and the opposite surface (bottom surface) Is concave. The pulse wave sensor 10 is disposed to be contained in the concave portion. A sheet sensor having such a plate 50 may be used.

  Moreover, although the sheet | seat part of the pulse wave sensor 10 is comprised with paper, materials other than paper may be sufficient. The pulse wave sensor 10 has a flat shape, but may have a shape other than the flat shape, for example, may have a curved shape. The pulse wave sensor 10 is an electret sensor, but may be another sensor such as another pressure sensor. Further, in the second embodiment, the inner plate 30 is smaller than the plate 20, but the inner plate 30 may have the same size as the plate 20.

1, 2 ... biological sensor, 10 ... pulse wave sensor, 20 ... plate, 30 ... internal plate, H ... biological body, S ... skin

Claims (5)

A plate having a curvature,
A sheet sensor disposed on the concave surface of the plate;
The biological sensor characterized by including.   The biological sensor according to claim 1, wherein the plate protrudes more than the outer end of the sheet sensor.   The biological sensor according to claim 1, wherein the plate has an arch shape or a dome shape.   The biosensor according to any one of claims 1 to 3, further comprising an internal plate provided on a surface opposite to the surface on the plate side of the sheet sensor.   The biological vibration emitted from a living body is detected by the sheet sensor which is disposed along the surface of the living body and provided on the surface closer to the living body than the plate, according to any one of claims 1 to 4. Biometric sensor.

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