The present invention relates to a component concentration measurement device for non-invasively measuring glucose concentration.
In terms of determining a dose of insulin for a diabetes patient or preventing diabetes, it is important to know (measure) blood sugar level. The blood sugar level is the concentration of glucose in blood, and as a way of measuring this kind of component concentration, a photoacoustic method is well known (see Patent Literature 1).
When a certain amount of light (an electromagnetic wave) is applied to a living body, the applied light is absorbed by molecules contained in the living body. As a result, target molecules for measurement in a portion applied with the light are locally heated to expand and generate a sound wave. The pressure of the sound wave depends on the amount of molecules that absorb the light. The photoacoustic method measures this sound wave to measure the amount of molecules in the living body. A sound wave is a pressure wave that propagates within a living body and has a property of being resistant to scattering compared to an electromagnetic wave; the photoacoustic method can be regarded to be a suitable way for measuring blood components in a living body.
Measurement by the photoacoustic method enables continuous monitoring of the glucose concentration in blood. In addition, measurement with the photoacoustic method does not require blood sample and causes no discomfort in a subject of measurement.
Patent Literature 1: Japanese Patent Laid-Open No. 2010-104858
A site on a human body that is subjected to this type of measurement (e.g., skin) changes in amount of moisture over time. For example, the amount of moisture in skin changes over a certain time period after eating or drinking. When the amount of moisture at the site of measurement thus changes, however, a measurement result of glucose measurement in a human body by the photoacoustic method will change. As the measurement result changes due to such a change in amount of moisture, it can happen that concentrations are actually the same when results that were measured at different times are different or that concentrations are actually different when results that were measured at different times are the same, which hinders an accurate measurement.
In order to solve such a drawback, an object of embodiments of the present invention is to suppress decrease in measurement accuracy that is caused by a change in moisture in a human body when glucose in a human body is measured by the photoacoustic method.
A component concentration measurement device according to embodiments of the present invention includes: a light application unit that applies beam light of a wavelength that is absorbed by glucose to a site of measurement; a detection unit that detects a photoacoustic signal which is generated at the site of measurement where the beam light emitted from the light application unit has been applied; a moisture measurement unit that measures an amount of moisture in skin at the site of measurement; and a correction unit that corrects an acoustic signal detected by the detection unit with the amount of moisture measured by the moisture measurement unit.
The component concentration measurement device may include a plurality of moisture measurement units, and the correction unit may correct the acoustic signal detected by the detection unit with an average of a plurality of amounts of moisture measured by the plurality of moisture measurement units.
In the component concentration measurement device, the light application unit may include a light source unit that generates the beam light of a wavelength that is absorbed by glucose; and a pulse control unit that turns the beam light generated by the light source unit into pulsed light of a set pulse width.
As described above, according to embodiments of the present invention, the amount of moisture in skin at the site of measurement is measured and an acoustic signal detected by the detection unit is corrected with the measured amount of moisture. Thus, it provides an advantageous effect of suppressing decrease in measurement accuracy that is caused by a change in moisture in a human body when glucose in a human body is measured by the photoacoustic method.
A component concentration measurement device according to an embodiment of the present invention is described below with reference to
For example, the light application unit 101 includes a light source unit 105 that generates the beam light 121 of a wavelength that is absorbed by glucose, and a pulse control unit 106 that turns the beam light 121 generated by the light source into pulsed light of a set pulse width. Glucose exhibits absorbency in light wavelength bands around 1.6 μm and around 2.1 μm (see Patent Literature 1). The beam light 121 has a beam diameter of about 100 μm, for example.
The component concentration measurement device also includes a moisture measurement unit 103 that measures an amount of moisture in skin at the site of measurement 151, and a correction unit 104 that corrects an acoustic signal detected by the detection unit 102 with the amount of moisture measured by the moisture measurement unit 103.
The moisture measurement unit 103 can be a dermometry-based (impedance-based) skin moisture meter, a capacitive skin moisture meter, or a microwave-based skin moisture meter, for example. The moisture measurement unit 103 may be positioned near a location to be applied with the beam light 121, for example. Alternatively, multiple moisture measurement units 103 may be positioned so as to surround the location to be applied with the beam light 121 and an average of measurement results from them may be used as the amount of moisture. The site of measurement 151 is a portion of a human body, like a finger or an ear lobe, for example.
The correction unit 104 corrects an acoustic signal detected by the detection unit 102 with an amount of moisture which has been measured by the moisture measurement unit 103 within a preset time from the point when the detection unit detected the acoustic signal. For example, the acoustic signal detected by the detection unit 102 is corrected with the amount of moisture which was measured by the moisture measurement unit 103 at the point when the detection unit 102 detected the acoustic signal. For example, a state of temporal change in the amount of moisture at the site of measurement 151 is measured in advance to determine an amount of time that causes a change in the amount of moisture that needs correction, and the aforementioned preset time may be set based on the result.
The light source unit 105 includes a first light source 201, a second light source 202, a drive circuit 203, a drive circuit 204, a phase circuit 205, a multiplexer 206, a detector 207, a phase detector-amplifier 208, and an oscillator 209 as shown in
The oscillator 209 is connected to each of the drive circuit 203, the phase circuit 205, and the phase detector-amplifier 208 via signal wires. The oscillator 209 sends a signal to each of the drive circuit 203, the phase circuit 205, and the phase detector-amplifier 208.
The drive circuit 203 receives the signal sent from the oscillator 209, and supplies driving electric power to the first light source 201, which is connected by a signal wire, to cause the first light source 201 to emit light. The first light source 201 is a semiconductor laser, for example.
The phase circuit 205 receives the signal sent from the oscillator 209, and sends a signal generated by giving a phase shift of 180 ° to the received signal to the drive circuit 204, which is connected by a signal wire.
The drive circuit 204 receives the signal sent from the phase circuit 205, and supplies driving electric power to the second light source 202, which is connected by a signal wire, to cause the second light source 202 to emit light. The second light source 202 is a semiconductor laser, for example.
The first light source 201 and the second light source 202 output light of different wavelengths from each other and direct their respective output light to the multiplexer 206 via light wave transmission means. For the first light source 201 and the second light source 202, the wavelength of light of one of them is set to a wavelength that is absorbed by glucose, while the wavelength of light of the other is set to a wavelength that is absorbed by water. Their respective wavelengths are also set such that degrees of their absorption will be equivalent.
The light output by the first light source 201 and the light output by the second light source 202 are multiplexed in the multiplexer 206 and are incident onto the pulse control unit 106 as one light beam. Upon incidence of the light beam, the pulse control unit 106 applies the incident light beam to the site of measurement 151 as pulsed light of a predetermined pulse width. Inside the site of measurement 151 thus applied with the pulsed light beam, a photoacoustic signal is generated.
The detector 207 detects the photoacoustic signal generated in the site of measurement 151, converts it into an electric signal, and sends it to the phase detector-amplifier 208, which is connected by a signal wire. The phase detector-amplifier 208 receives a synchronization signal necessary for synchronous detection sent from the oscillator 209, and also receives the electric signal proportional to the photoacoustic signal being sent from the detector 207, performs synchronous detection, amplification and filtering on it, and outputs an electric signal proportional to the photoacoustic signal.
The first light source 201 outputs light that has been intensity-modulated in synchronization with an oscillation frequency of the oscillator 209. In contrast, the second light source 202 outputs light that has been intensity-modulated with the oscillation frequency of the oscillator 209 and in synchronization with the signal that has gone through a phase shift of 180° in the phase circuit 205.
Here, since the intensity of the signal output by the phase detector-amplifier 208 is proportional to the amount by which the light output from each of the first light source 201 and the second light source 202 was absorbed by components (glucose, water) in the site of measurement 151, the intensity of the signal is proportional to the amounts of components in the site of measurement 151.
As mentioned above, the light output by the first light source 201 and the light output by the second light source 202 have been intensity-modulated with signals of the same frequency. Accordingly, there is no effect of unevenness in frequency characteristics of a measurement system, which is problematic in the case of intensity modulation with signals of multiple frequencies.
Meanwhile, non-linear dependence on absorption coefficient that exists in measured values of photoacoustic signals, which is problematic in measurements by the photoacoustic method, can be solved by performing measurements using light of multiple wavelengths that gives an equal absorption coefficient as described above (see Patent Literature 1).
As mentioned above, the intensity of the acoustic signal output by the detection unit 102 is corrected by the correction unit 104, and based on a corrected correction value, a component concentration derivation unit (not shown) determines the amount of glucose component in blood within the site of measurement 151.
Next, correction by the correction unit 104 of an acoustic signal detected by the detection unit 102 with an amount of moisture measured by the moisture measurement unit 103 is described.
In a one-dimensional system, a photoacoustic signal at time t for a substance having a certain concentration distribution is represented as Formula (1).
In Formula (1), P is the output of the photoacoustic signal, β(x, t) is an absorption coefficient at depth x and at a given wavelength when a radiation end surface of the light source is defined as x=o, and μs is thermal diffusion length.
The value β(x, t) in Formula (1) changes either when a target component concentration c changes or when a moisture content w changes, so that when considering measurement of skin, β(x, t) would be shown by “β(x, t)=w(t)×{c(t)+ce(t)}. . . (2)”. The term ce(t) is absorption by components other than the target component.
As will be apparent from Formulas (1) and (2), an acoustic signal also changes when there is a change in the moisture content. Here, a measurement result with the moisture measurement unit 103 can be represented by a linear expression such as “ε(t)=w(t)×α×εwater . . . (3)”. The value ε(t) is a dielectric constant as measured by the moisture measurement unit 103, εwater is the dielectric constant of water, and α is an arbitrary coefficient.
The relationship of Formula (3) (the relationship between the dielectric constant measured and the moisture content at the location of measurement) is indicated as in
The Δw(t) in Formula (4) for correction of moisture is measured at the same timing as the acquisition of the photoacoustic signal. Using such a correction, β(x, t)/Δw(t) will always be “β(x, t)/Δw(t)=w(to)·{c(t)+ce(t)}. . . (6)”, so that the effect of moisture content can be suppressed.
The correction described above enables an accurate measurement of a change in the concentration of the target component. Additionally, for dual wavelength photoacoustic signals, an increased accuracy of dual wavelength differential measurement can be expected by applying Formula (5) to each wavelength.
As has been described above, according to the present invention, the amount of moisture in skin at the site of measurement is measured and an acoustic signal detected by the detection unit is corrected with the measured amount of moisture. Thus, it is possible to suppress decrease in measurement accuracy that is caused by a change in moisture in a human body when glucose in a human body is measured by the photoacoustic method.
It will be apparent that the present invention is not limited to the above-described embodiments but many variations and combinations may be made by ordinarily skilled persons in the art within the technical idea of the invention.
101 light application unit
102 detection unit
103 moisture measurement unit
104 correction unit
105 light source unit
106 pulse control unit
121 beam light
151 site of measurement.
Number | Date | Country | Kind |
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2018-109400 | Jun 2018 | JP | national |
This application is a national phase entry of PCT Application No. PCT/JP2019/019738, filed on May 17, 2019, which claims priority to Japanese Application No. 2018-109400, filed on Jun. 7, 2018, which applications are hereby incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/019738 | 5/17/2019 | WO | 00 |