JP2001120521A - Cuff for measuring blood sugar level - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cuff used for restricting a measuring object part of an organism and capable of easily improving measuring accuracy of a blood sugar level in noninvasive measurement of blood sugar level. SOLUTION: This cuff is used for restricting a finger F to a prescribed position in a blood sugar level measuring apparatus for determining a blood sugar level in the organism on the basis of a transmitted light intensity value obtained by detecting intensity of a transmitted light beam 7 by irradiating an irradiating light beam 3 to the finger F of the organism, and is provided with a balloon 12 arranged in a finger arranging cavity 4 of the blood sugar level measuring apparatus and a gas injection/exhaust pipe 14 connected to the balloon 12. The balloon 12 has an outside surface abutting to an inside surface of a finger arranging cavity forming member 6 by injection of gas and an inside surface abutting on the back side of finger F by injection of the gas, and a base 16 is adapted to a cavity forming member opening 6a to secure an optical path for light irradiation. The balloon 12 is allowed to abut to the finger in a range of surrounding 90 deg. to 270 deg. from the finger F and the back side by injection of the gas.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cuff used for non-invasively measuring a blood glucose level in a living body using an optical method.

[0002]

2. Description of the Related Art Diabetics frequently (e.g., daily) receive an indication of insulin administration for controlling blood sugar levels (generally, blood glucose levels). It is required to measure the blood glucose level several times. Sampling blood at each such frequent measurement is a great pain for the patient.
Therefore, it is desired to measure the blood glucose level without actually collecting blood from the patient, that is, non-invasively, and as a method for this, infrared light is applied to a part of the patient, for example, a measurement site such as an earlobe or a finger. It has been proposed to detect the infrared light transmitted through the measurement site and to measure the degree of infrared absorption by the measurement site. In this method, by appropriately selecting the wavelength of the infrared light to be used, an absorbance value that reflects the infrared absorption by glucose in the measurement site to a considerable extent is obtained, and a blood glucose value is obtained based on the absorbance value.

[0003] In such optical non-invasive blood glucose measurement, however, the absorbance obtained by measuring the absorbance at the site to be measured is also affected by infrared light absorption by biological components other than blood. Yes, it is preferable to reduce as much as possible the influence of the biological constituents other than blood on the absorbance value from the viewpoint of improving the accuracy of blood glucose measurement.

[0004] One method for improving the accuracy of blood glucose measurement is to use the fluctuation range of the absorbance value that fluctuates periodically with pulsation. That is, the fluctuation range of the absorbance value is the difference between the absorbance of the measurement site where blood has flowed to the maximum and the absorbance of the measurement site where blood has flowed to the maximum. It is considered that the influence of the components was excluded and the light absorption by blood alone was reflected.

It has been pointed out that as one method for improving the accuracy of blood glucose measurement, it is possible to perform measurement using a second derivative of the absorbance instead of obtaining the blood glucose from the absorbance itself. (See Japanese Patent Application Laid-Open No. 5-176917). In this method, the absorbance is measured at three wavelengths that are different and close to each other, and a variation (absorbance second derivative value) corresponding to the second derivative calculated by adding and subtracting from the measured absorbance values is used for blood glucose measurement. I do.

[0006] Even when measuring the blood sugar level based on the second derivative of the absorbance, the absorbance value is first obtained. Therefore, in order to improve the accuracy of the blood sugar level measurement, it is necessary to absorb infrared light by blood in a living body. It is important to obtain an absorbance value that reflects only the effect of

On the other hand, when measuring absorbance for non-invasive blood sugar level measurement, the measurement site must be kept constant in order to maintain a constant irradiation state of the infrared light to the measurement site within a required measurement time. Measured portion restraining means for maintaining a predetermined position and posture with respect to the irradiated infrared light beam is used. When the measurement site is a finger, a cuff accommodated in a cavity for arranging the measurement site formed in the measuring device can be used as such a restraining means. This cuff consists of a balloon that can be inflated and discharged so as to cover the required length of the finger from the entire circumference.At the time of measurement, air is injected into the cuff so that it can be placed on the optical path of the irradiation beam. Thus, it is possible to maintain a predetermined posture with the fingers pressed.

By using such a cuff, the absorbance can be measured without damaging the fingers and without causing any pain to the living body.

However, when the conventional cuff as described above is used as the restraining means for the measurement site, the finger is pressed from the outside over the entire circumference, so that the blood volume at the measurement site is reduced, and the blood volume at the measurement site is reduced. The obtained absorbance value has a high rate of influence of infrared light absorption by living body components other than blood. Therefore, when a conventional cuff is used, considerable difficulty is involved in sufficiently improving the accuracy of blood glucose measurement based on the obtained absorbance value.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cuff which is used for non-invasive measurement of blood glucose level and is used for restraining a site to be measured in a living body and which can easily improve the blood glucose level measurement accuracy. is there.

[0011]

According to the present invention, as a means for achieving the above object, a transmitted light intensity obtained by irradiating a finger of a living body with light and detecting the intensity of light transmitted through the finger is obtained. A cuff used for restraining the finger at a predetermined position in a blood sugar level measuring device for obtaining a blood sugar level in the living body based on the value, wherein the cuff is provided in a finger placement cavity formed in the blood sugar level measuring device. A balloon to be disposed, and an injection / discharge pipe connected to the balloon for injecting / discharging a gas to / from the balloon, wherein the balloon is a member that forms the finger placement cavity by gas injection. It has an outer surface that is brought into contact with the inner surface and an inner surface that is brought into contact with the back side of the finger inserted into the cavity by gas injection, and has a shape in which an optical path for the light irradiation is secured. Without Blood glucose measurement cuff, wherein, is provided.

In one aspect of the present invention, the balloon has a flat first flexible sheet constituting the outer side surface, and unevenness partially joined to one side of the first flexible sheet on one side. A second flexible sheet, wherein a gas containing space is formed between the first flexible sheet and the second flexible sheet, and the second flexible sheet is formed. The inner side surface is constituted by the convex portion of the sheet.

In one embodiment of the present invention, the optical path for the light irradiation in the balloon is secured by forming an opening in a region other than the region where the gas accommodating space is formed in the balloon. I have.

In one embodiment of the present invention, the balloon is formed by injecting gas into the finger and the back side or around 90 ° to 270 °.
The contact is made within the range of °.

[0015]

Embodiments of the present invention will be described below with reference to the drawings.

FIGS. 1 and 2 are schematic sectional views showing one embodiment of a blood sugar level measuring cuff according to the present invention, together with a part of a blood sugar level measuring apparatus.

In FIGS. 1 and 2, reference numeral 2 denotes a light source of the blood sugar level measuring device. As the light source, for example, a semiconductor laser emitting near-infrared light can be used. The irradiation light beam 3 emitted from the light source 2 passes through an irradiation optical system such as a reflector and a collimator lens (not shown), and is made to enter the finger placement cavity 4 of the blood sugar level measuring device. That is,
A light passage opening 6a is formed in the upper part of the cavity forming member 6 forming the cavity 4 of the blood sugar level measuring device, and the irradiation light beam 3 enters the cavity 4 from the light passage opening 6a.

The cavity 4 has a cylindrical shape as shown in the drawing (the direction is a horizontal direction parallel to the plane of FIG.
In FIG. 2, the direction is a direction perpendicular to the plane of the drawing), and at the time of measuring the blood sugar level, a living body such as a finger F of a human body, which is a measurement site of the blood sugar level measurement, is inserted along the direction. The finger F has a light passing opening 6a at the second joint portion.
Is inserted so as to be positioned corresponding to.

At the time of measuring the blood sugar level, a part of the irradiation light beam 3 that has entered the cavity 4 passes through the finger F and exits the cavity 4. That is, a light passage opening 6b is formed at a lower portion of the cavity forming member 6 in correspondence with the light passage opening 6a, and the transmitted light beam 7 transmitted (passed) through the finger F passes through the cavity 4 downward from the light passage opening 6b. Go outside. In addition, a light-transmitting window member may be attached to the light passage opening 6b.

A light detector 8 is arranged below the light passage opening 6b, and detects the intensity of the transmitted light beam 7 by this. The light detector 8 is a device (for example, a spectroscope) that can detect the intensity of near-infrared light having a wavelength (or a plurality of wavelengths) suitable for measuring a blood sugar level. Although not shown, the blood glucose level measuring device calculates the absorbance of the finger F, which is the measurement site, using the near-infrared light intensity detected by the light detector 8 and the intensity of the light emitted from the light source, By performing a predetermined calculation based on this, the blood glucose level of the living body can be obtained.

In the present embodiment, a cuff 10 used to restrain the finger F at a predetermined position in the cavity 4 is provided. The cuff 10 includes a balloon 12 and a gas injection / discharge pipe 14 connected to the balloon 12.

FIG. 3 shows a state in which the balloon 12 is deployed. In FIG. 3, (A) is a plan view, and (B) and (C) are a BB ′ sectional view and a CC ′ sectional view, respectively. The balloon 12 is formed by joining a flat first flexible sheet 12a and an uneven second flexible sheet 12b. First sheet 12a and second sheet 1
2b is made of, for example, a silicone resin. 2nd sheet 1
2b is joined to the first sheet 12a at an outer peripheral portion, and a gas containing space 12c is formed between the two sheets 12a and 12b. In addition, balloon 1
2, an opening 12d is formed at the center to secure an optical path for light irradiation. And the first sheet 1
The 2a and the second sheet 12b are also joined at a portion around the opening 12d. The second sheet 12b is formed thinner than the first sheet 12a, and the first sheet 12a
Is formed with an opening 12e for communicating the gas injection / discharge pipe 14 with the gas storage space 12c at the mounting position of the gas injection / discharge pipe 14.

As shown in FIGS. 1 and 2, the balloon 12 has a base 16 at the opening 12d for securing an optical path.
The cuff 10 can be attached to the blood sugar level measuring device by fitting the base 16 to the light passage opening 6a and fixing the base 16 to the cavity forming member 6 by appropriate means. As shown in FIG.
The balloon 12 disposed inside is curved along the inner surface of the cavity forming member 6, the outer surface is constituted by the first sheet 12a, and the inner surface is constituted by the second sheet 12b. The balloon 12 may be formed into a curved shape so as to fit the inner surface of the cavity forming member 6 as shown in FIG. 2 in advance, or may be formed into a planar shape as shown in FIG. May be forcibly deformed into a curved shape by being accommodated in the cavity forming member 6.

When measuring the blood sugar level, the gas injection / discharge pipe 14 is used.
By injecting gas into the balloon 12 by supplying air from a gas supply source (not shown), for example, an air pump, connected to the balloon 12, the volume of the gas storage space 12c in the balloon 12 increases, and the first sheet 12a forms a cavity. The inner surface of the member 6 is abutted, and the protrusion of the second sheet 12b is abutted on the back side of the finger F. That is, the cuff 10 is arranged on the back side of the finger F, and a range of an angle θ around the finger F (a direction connecting the back side of the finger F and the opposite side [in the figure, coincident with the irradiation light beam 3. Is almost symmetric). The angle theta, but there is a 180 ° in the figure, is not limited to this, it is possible to make a proper angle from the minimum angle theta ₁ to the maximum angle theta _2. The minimum angle θ ₁ is, for example, 90 °, and the maximum angle θ ₂ is, for example, 270 °.

In this way, the finger F is pressed from the back side by the cuff 10 (ie, at least the side opposite to the back side is not pressed by the cuff 10), and the finger F is moved to a predetermined position and a predetermined posture. In this state, the light beam is irradiated to measure the absorbance and measure the blood sugar level based on the absorbance.

FIG. 4 shows a time change X of the absorbance obtained when the cuff of the present embodiment is used and a time change of the absorbance obtained when a conventional cuff for pressing a finger from all around is used for comparison. Y. From FIG. 4, it can be seen that the change in absorbance due to pulsation (this corresponds to the change in blood volume in the finger) is greater in the present embodiment than in the conventional one. That is, the absorbance signal obtained by using the cuff of the present embodiment is less affected by the absorption of biological components other than blood than the absorbance signal obtained by using the conventional cuff. Is reflected favorably.

As described above, the reason why a good absorbance signal is obtained by the present embodiment is that the main artery and the main vein in the finger F are located on both sides on the palm side, so that the entire circumference is different from the conventional one. Although the blood flow is suppressed by the compression from the front side, the cuff 1 is located on the side opposite to the back side as in the embodiment of the present invention.
It is considered that one factor is that the blood flow flowing through the main artery and the main vein is sufficiently ensured by preventing the compression by zero.

It is to be noted that the "fingers" in the present invention include toes (that is, fingers of limbs).

[0029]

As described above, according to the cuff for measuring blood sugar level of the present invention, it is possible to obtain an absorbance value that well reflects the light absorption by blood, and to obtain a blood sugar level based on this. Measurement accuracy is improved.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional view showing one embodiment of a blood sugar level measuring cuff according to the present invention together with a part of a blood sugar level measuring apparatus.

FIG. 2 is a schematic sectional view showing one embodiment of a blood sugar level measuring cuff according to the present invention together with a part of a blood sugar level measuring apparatus.

FIG. 3 is a view showing a state where a balloon is deployed.

FIG. 4 shows a time change of absorbance obtained when an embodiment of the cuff for measuring blood glucose level according to the present invention is used, and an absorbance obtained when a conventional cuff for pressing a finger from all around is used for comparison. FIG. 5 is a diagram showing a time change of the first embodiment.

[Explanation of symbols]

 Reference Signs List 2 light source 3 irradiation light beam 4 finger placement cavity 6 cavity forming member 6a, 6b light passage opening 7 transmitted light beam 8 photodetector 10 cuff 12 balloon 12a first flexible sheet 12b second flexible sheet 12c Gas storage space 12d Opening for securing optical path 12e Opening 14 Gas injection / discharge pipe 16 Base F Finger

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Tsutomu Makino 2-88 Ogihigashi, Komaki-shi, Aichi F-term (reference) 2G059 AA01 AA05 BB12 CC16 DD13 EE01 FF06 GG01 HH01 JJ11 JJ13 KK01 LL02 PP02 4C017 AA06 AB03 AC26 AD01 4C038 KK10 KL07 KM01 KY04

Claims (4)

[Claims] 1. A blood sugar level measuring device for irradiating a finger of a living body with light and detecting the intensity of light transmitted through the finger to obtain a blood sugar level in the living body based on a transmitted light intensity value obtained from the finger. A cuff used for restraining a position, wherein the balloon is disposed in a finger placement cavity formed in the blood glucose level measuring device, and is connected to the balloon to inject and discharge gas to and from the balloon. An injection / drainage tube for performing the operation, wherein the balloon has an outer surface brought into contact with an inner surface of a member forming the finger placement cavity by gas injection, and a finger inserted into the cavity by gas injection. A cuff for measuring a blood glucose level, the cuff having an inner surface which is brought into contact with the back side of the blood vessel, and having a shape in which an optical path for the light irradiation is secured. 2. The balloon according to claim 1, wherein the balloon comprises a flat first flexible sheet constituting the outer surface, and an uneven second flexible sheet partially joined to one side of the first flexible sheet. A flexible sheet, a gas storage space is formed between the first flexible sheet and the second flexible sheet, and the convex portion of the second flexible sheet defines the gas containing space. The blood sugar level measurement cuff according to claim 1, wherein an inner side surface is configured. 3. The securing of an optical path for the light irradiation in the balloon is performed by forming an opening in a region of the balloon other than a region where the gas storage space is formed. The cuff for measuring a blood sugar level according to claim 2. 4. The balloon according to claim 1, wherein the balloon is brought into contact with the finger from the back side within a range of 90 ° to 270 ° by gas injection.
3. The blood sugar level measurement cuff according to any one of 3.