JP2006058263A - Apparatus and program for measuring biological information - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow biological information to be measured readily by anyone at any location, when a biosensor is used to measure biological information. <P>SOLUTION: A specimen adhesive sheet 1 is provided with an adhesive layer 14 on one side of a thin-film substrate 13, and a peeling layer 15 is provided and peelably bonded to the adhesive layer 14. The biosensor 16 and a RFID 18 are disposed in between the adhesive layer 14 and the peeling layer 15. A constitution transmits and outputs a sensor ID set to the RFID 18 and the biological information acquired by the biosensor 16. A portable information terminal, for transmitting and receiving the information between the specimen adhesive sheet 1, receives the sensor ID transmitted and outputted from the RFID 18 and the biological information, maps the sensor ID to biological measured values, stores and manages them, and guides and outputs the biological measured values; while the specimen adhesive sheet 1 is bonded to a specimen through the adhesive layer 14 by peeling the peeling layer 15 of the specimen adhesive sheet 1. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a biological information measuring apparatus and a program for measuring biological information using a biosensor that detects a change in biological reaction on a membrane on which a biological substance is immobilized.

In general, a biosensor using the substance detection capability of a living body is composed of a membrane on which the biological material is immobilized and an electrochemical device. When a biological reaction occurs on the membrane, the electrochemical device detects the change. Thus, it is converted into an electrical signal, and is classified into an enzyme sensor, an immune sensor, a microorganism sensor, and the like according to a biological substance. In this case, the enzyme sensor has been put to practical use in the fields of medicine, food, fermentation, etc. However, when the enzyme sensor is periodically replaced or repeatedly used, the electrode part is washed to obtain a new enzyme. Needed to be restored.
By the way, conventionally, there is known a method of measuring a measurement target substance in a sample solution by connecting an electrode part on the biosensor side to an electrode part on the measuring device side (see Patent Document 1).
JP 2001-21526 A

  However, in the configuration in which the biosensor is directly connected to the measurement device as in the above-mentioned patent document, the biosensor and the measurement device are always inseparable, and the overall configuration becomes large or requires maintenance management. As a result, it was limited to use in specialized fields such as medical institutions, and general people could not use it easily. In addition, each time the sensor is used repeatedly, it is necessary to clean the electrode portion.

  An object of the present invention is to make it possible for anyone to easily measure biological information anywhere by using a biosensor.

The invention described in claim 1 is a biological information measuring device that measures biological information using a biosensor that detects a change in biological reaction on a membrane on which a biological substance is immobilized, and is provided on one side of a thin film substrate. An adhesive layer is provided, and a release layer that is detachably attached to the adhesive layer is provided, and the biosensor and the electronic tag are arranged between the adhesive layer and the release layer, and set in the electronic tag. The specimen adhesive sheet that transmits and outputs the sensor identification information and the biological information obtained by the biosensor, and the specimen adhesive sheet is peeled off the specimen by the adhesive layer by peeling off the peeling layer constituting the specimen adhesive sheet. The receiving means for receiving the sensor identification information and the biological information transmitted and output in the bonded state, and the sensor identification information and the biological information obtained by the receiving means are associated with each other. And information storing means for storing supervises as, characterized by comprising a portable information terminal and an output means for outputting the contents of the information storage means.
Further, a program for realizing the main functions shown in the invention described in claim 1 is provided to the computer (the invention described in claim 11).
The biosensor uses the substance detection capability of the living body, but in a broad sense, it means that the living body sensor can detect information about the living body through the skin (hereinafter the same). .

The invention described in claim 1 may be as follows.
The thin film substrate of the specimen pressure-sensitive adhesive sheet is constituted by a flexible film member so that it can be attached to a curved specimen (claim 2).

  The electronic tag in the specimen pressure-sensitive adhesive sheet is an RFID tag with an antenna, accumulates electric energy of received radio waves received by the antenna, and transmits and outputs the sensor identification information and biological information using the accumulated energy. (Invention of Claim 3). An RFID (Radio Frequency Identification) tag is a microchip that communicates using radio waves, and uses a non-contact power transmission technique to make a battery unnecessary (the same applies hereinafter).

  The portable information terminal includes an antenna that transmits and receives radio waves to and from the specimen adhesive sheet, and also includes a monitoring unit that monitors whether a predetermined measurement timing has been reached, and the measurement timing When it is detected that the sensor has arrived, sensor identification information and biological information are transmitted and output from the specimen adhesive sheet by feeding power to the antenna (invention according to claim 4).

Whether the portable information terminal has received correction value storage means for storing a correction value for correcting biological information for each elapsed time after the specimen adhesive sheet is newly attached, and whether new sensor identification information has been received. A discriminating means for discriminating whether or not a new specimen adhesive sheet is attached based on whether or not a new specimen adhesive sheet is attached by the discriminating means. There is provided time measuring means for measuring the elapsed time since being performed, and correction means for reading out a correction value corresponding to the elapsed time obtained by the time measuring means from the correction value storage means and correcting biological information at the time of the elapsed time. (Invention of Claim 5)
In this case, the correcting unit may determine the type of the biosensor based on the received sensor identification information, and may correct the biometric information with a correction value corresponding to the type of the biosensor. Invention).

  When the same type of sensor is newly installed instead of the currently installed biosensor and the sensor is replaced, the living body obtained by the sensor that has been installed and the newly installed sensor Information is stored and managed as continuous information (invention of claim 7).

  Each time the portable information terminal receives sensor identification information, the portable information terminal compares the received sensor identification information with preset sensor identification information to determine whether the portable information terminal is a legitimate biosensor. And the biometric information is stored and managed in correspondence with the sensor identification information on the condition that it is determined that the biosensor is a normal biosensor by the determination means (the invention according to claim 8).

  The portable information terminal is configured to determine whether or not a new sample adhesive sheet has been mounted based on whether or not new sensor identification information has been received, and the new sample adhesive sheet is mounted by the determination unit. When it is determined that the time has elapsed, the time measuring means for measuring the elapsed time since the specimen adhesive sheet was attached and the elapsed time obtained by the time measuring means have reached a predetermined sensor replacement time. And an informing means for informing that the current specimen adhesive sheet attached to the specimen should be exchanged (invention of claim 9).

  The output means displays the transition state in a graph based on a plurality of pieces of biological information stored and managed in association with the same sensor identification information in the information storage means (invention according to claim 10).

  According to the first aspect of the present invention, the adhesive layer is provided on one surface of the thin film substrate, the release layer adhered to the adhesive layer in a peelable manner is provided, and the biosensor is provided between the adhesive layer and the release layer. A specimen adhesive sheet for transmitting and outputting sensor identification information set in the electronic tag and biological information obtained by the biosensor, and a transmission / reception operation between the specimen adhesive sheet. A portable information terminal, and the portable information terminal has an electronic component in the specimen pressure-sensitive adhesive sheet in a state where the specimen pressure-sensitive adhesive sheet is adhered to the specimen by the pressure-sensitive adhesive layer by peeling off the peeling layer constituting the specimen pressure-sensitive adhesive sheet. Since the sensor identification information and the biological information transmitted from the tag are received, the sensor identification information and the biological information are associated with each other, stored, managed, and output. It is possible to adopt a configuration in which separating the sheet and the portable information terminal, it is only pasting the specimen adhesive sheet such as human skin, the anyone anywhere easily it is possible to measure the biological information. In this case, even if the specimen adhesive sheet and the portable information terminal are separated, the portable information terminal stores and manages the sensor identification information and the biological information in association with each other, so that the specimen adhesive sheet may be inadvertently peeled off. Even if the specimen adhesive sheet is replaced with a new one, the correspondence between the sensor and the measurement result can be held, and the biological information can be accurately measured. Furthermore, since the specimen adhesive sheet can be separated from the portable information terminal and can be configured at low cost, for example, even when the detection capability of the biosensor deteriorates, the biological adhesive information can be detected by replacing the specimen adhesive sheet. Is possible.

  According to the second aspect of the invention, in addition to the same effects as the first aspect of the invention described above, the thin film substrate of the specimen pressure-sensitive adhesive sheet is a flexible film so that it can be attached to a curved specimen. Since it is configured by the member, the specimen adhesive sheet can be reliably attached to any part of the human body.

  According to the invention described in claim 3, in addition to having the same effect as that of the invention described in claim 1, the electronic tag in the specimen adhesive sheet is an RFID tag with an antenna, and the received radio wave received by this antenna. Since the sensor identification information and biological information are transmitted and output using this stored energy, the battery can be made unnecessary by the non-contact power transmission technology, and the sample adhesive sheet can be made compact. Thinning can be realized.

  According to the invention described in claim 4, in addition to having the same effect as that of the invention described in claim 1, the portable information terminal has an antenna that transmits and receives radio waves to and from the specimen adhesive sheet. It is monitored whether or not a predetermined measurement timing has been reached, and when it is detected that this measurement timing has been reached, power is supplied to the antenna to transmit and output sensor identification information and biological information from the specimen adhesive sheet. As a result, the power consumption can be suppressed, and the built-in battery can have a long service life.

  According to the invention described in claim 5, in addition to having the same effect as that of the invention described in claim 1, the portable information terminal can perform a new specimen adhesion based on whether or not new sensor identification information is received. It is determined whether or not a sheet is attached, and when a new specimen adhesive sheet is attached, the elapsed time since the specimen adhesive sheet is attached is counted, and the correction value corresponding to this elapsed time Since the biological information at the time of correction is corrected, even if biological materials such as enzymes that make up the biosensor deteriorate due to changes over time, the effect can be prevented and biological information can always be measured accurately. It becomes possible.

  Here, if the type of the biosensor is determined based on the received sensor identification information, and the biological information is corrected with a correction value corresponding to the type of the biosensor (the invention according to claim 6), the sensor is It is possible to correct the influence of deterioration of the constituent biological material for each type of sensor.

  According to the invention described in claim 7, in addition to having the same effect as the invention described in claim 1 described above, a sensor of the same type is newly mounted in place of the currently mounted biosensor so that the sensor can be replaced. When performed, the biometric information obtained by the previously installed sensor and the newly installed sensor is stored and managed as continuous information, so that the specimen adhesive sheet is inadvertently peeled off. Even if the sample adhesive sheet is replaced with a new one, the correspondence between the sensor and the measurement result can be maintained, and the biological information can be accurately measured.

  According to the invention described in claim 8, in addition to having the same effect as that of the invention described in claim 1, the portable information terminal is preset with the received sensor identification information every time the sensor identification information is received. The biometric information corresponding to the sensor identification information is determined on the condition that the biosensor is a legitimate biosensor. For example, it is possible to effectively prevent a third party other than the person wearing the specimen adhesive sheet from using the portable information terminal to steal biological information. Therefore, it is possible to perform secure security management of personal information such as biometric information.

  According to the ninth aspect of the invention, in addition to having the same effect as that of the first aspect of the invention described above, the portable information terminal can perform new specimen adhesion based on whether or not new sensor identification information has been received. A sensor that determines whether or not a sheet has been mounted and measures the time elapsed since the sample adhesive sheet was mounted when a new sample adhesive sheet was mounted. When it is detected that the replacement time has been reached, the fact that the current sample pressure-sensitive adhesive sheet attached to the sample should be replaced is notified so that the time to replace the sample pressure-sensitive adhesive sheet can be immediately known. More accurate measurement is possible.

  According to the invention described in claim 10, in addition to the same effect as the invention described in claim 1, the transition state based on a plurality of pieces of biological information stored and managed in association with the same sensor identification information Is displayed in a graph, so that, for example, not only one measurement result such as the maximum value but also a change with time can be known.

Hereinafter, embodiments of the present invention will be described with reference to FIGS.
FIG. 1 is an external view showing a state in which the specimen adhesive sheet 1 and the portable information terminal 2 are attached to the human arm, and FIG. 2A is an overall side view of the specimen adhesive sheet 1. B) is an enlarged cross-sectional view of the main part of the specimen pressure-sensitive adhesive sheet 1.
The specimen adhesive sheet 1 is a small and thin sheet member, and is configured by a flexible (flexible) member so that it can be attached to a curved specimen. As shown in FIG. 2A, the specimen adhesive sheet 1 has a bulging portion 11 whose central portion bulges downward (specimen side) and a peripheral portion 12 surrounding the bulging portion 11. FIG. 2B is an enlarged cross-sectional view of the bulging portion 11. The portable information terminal 2 is a wristwatch with an antenna, and the specimen adhesive sheet 1 mounted near the wrist and the portable information terminal 2 are in a positional relationship close to each other in distance.

  The specimen adhesive sheet 1 is provided with an adhesive layer 14 on one side of the thin film substrate 13, a release layer 15 that is detachably bonded to the adhesive layer 14, and a gap between the adhesive layer 14 and the release layer 15. The biosensor 16 and the electronic tag 18 with the antenna 17 are disposed, and the intermediate protective layer 19 is disposed between the biosensor 16 and the electronic tag 18 with the antenna 17 and the release layer 13. The thin film substrate 13 is a surface protective layer made of a flexible film member so that it can be attached to a curved sample. The peeling layer 15 is detachably bonded to the adhesive layer 14, and the specimen adhesive sheet 1 is adhered to the specimen (human body) by the adhesive layer 14 in the peripheral portion 12 by peeling off the peeling layer 15. . The peripheral portion 12 is composed of a thin film substrate 13, an adhesive layer 14, and a release layer 15. By peeling off the release layer 15, the adhesive layer 14 of the peripheral portion 12 is adhered to the human body. 1 is mounted. In this case, the biosensor 16 is a skin contact type sensor that directly contacts the human skin by detecting the release layer 15 and detects biological information obtained through the skin. The specimen adhesive sheet 1 will be described based on an example in which the specimen adhesive sheet 1 is worn on the inner side of the arm near the wrist as a part of the human body having a relatively small stratum corneum. Also good.

  The biosensor 16 is an enzyme sensor, for example, a glucose sensor that detects glucose (blood glucose level), an odor sensor that detects odor, and the like. The enzyme sensor reduces the electron acceptor produced by the reaction between the substrate contained in the specimen and the enzyme. By measuring the amount of reduction electrochemically, glucose and other information can be measured as biological information of the specimen. Used when doing. An electronic tag 18 with an antenna 17 is an RFID (Radio Frequency Identification) tag, which is a microchip that communicates using radio waves, and uses a non-contact power transmission technique and does not require a battery. Hereinafter, the electronic tag is referred to as RFID. The intermediate protective layer 19 is disposed below the RFID 18 with the biosensor 16 and the antenna 17 to protect them, and is configured by an adhesive layer having elasticity. The intermediate protective layer 19 is formed of a thin film member and is provided in the bulging portion 11 other than the peripheral portion 12 of the specimen adhesive sheet 1, and the adhesive layer 14 in the peripheral portion 12 is peeled off by peeling off the release layer 15. Bonded to the human body. In this case, as described above, the portion of the intermediate protective layer 19 corresponding to the biosensor 16 is opened so that the biosensor 16 comes into direct contact with the human skin by peeling off the release layer 15. The biosensor 16 comes into contact with the skin through the opening.

FIG. 3 is a view when the peeling layer 15 and the intermediate protective layer 19 are removed from the specimen pressure-sensitive adhesive sheet 1 and the whole specimen pressure-sensitive adhesive sheet is viewed from the back side (sample side).
Here, to the RFID 18, an antenna 17 that is looped around the entire specimen adhesive sheet 1 is connected via a lead wire 17 </ b> R, and a biosensor 16 is connected via a lead wire 16 </ b> R. Here, FIG. 4A is a side view of the RFID 18, and FIG. 4B is a back view thereof. As shown in FIG. A sensor electrode 18ST is provided. That is, the antenna electrode 18AT is provided on the front surface side of the RFID 18, and the sensor electrode 18ST is provided on the back surface side (sample side). In this case, the pair of antenna electrodes 18AT provided on the front surface side of the RFID 18 is connected to the antenna 17 via the lead wire 17R, and the pair of sensor electrodes provided on the back surface side (specimen side) of the RFID 18. 18ST is connected to the biosensor 16 via a lead wire 16R.

FIG. 5 is an external front view of the portable information terminal (watch) 2.
The portable information terminal 2 constitutes, for example, a digital display wristwatch, and an annular RFID antenna 22 is provided on the upper surface of the watch case 21. The installation position of the RFID antenna 22 is arbitrary, and the RFID antenna 22 may be provided on the inner peripheral surface of the opening of the watch case 21 or may be provided near the inner wrist of the watch band. Good. Since the inside of the wrist has a thin stratum corneum and is suitable as a site for biometric measurement, when the specimen adhesive sheet 1 is attached to the inside of the arm near the wrist, an RFID antenna is placed near the inside wrist of the watch band. If 22 is provided, even if the radio wave arrival range is narrow, that is, even if the transmission radio wave intensity or the reception radio wave sensitivity is low, it is possible to always transmit and receive data reliably. When the specimen adhesive sheet 1 is affixed to other parts of the human body with few stratum corneum, the portable information terminal 2 is positioned in the vicinity of the specimen adhesive sheet 1 at each measurement and data is transmitted and received. .

FIG. 6 is a diagram illustrating a circuit configuration of the RFID 18.
The RFID 18 has the CPU 101 as a core, and when the radio wave transmission / reception unit 102 connected to the antenna 17 and the radio wave transmission / reception unit 102 detect a radio wave received from the antenna 17, the detection signal is converted into a DC voltage or a DC current. The rectifying / smoothing unit 103 for converting the data into the storage unit 104, the storage unit 104 for storing the electric energy obtained by the received radio wave, the sensor identification information and the like are stored, and the EEPROM 105 capable of erasing the stored contents are connected to the biosensor 16. The measurement circuit 106 is provided.

  Here, the CPU 101, the radio wave transmission / reception unit 102, the EEPROM 105, and the measurement circuit 106 operate using the electrical energy stored in the storage unit 104 as a power source. The measurement circuit 106 changes the biological reaction detected by the biosensor 16. Is measured as biological information and given to the CPU 101. Here, the CPU 101 gives the biometric information obtained by the measurement circuit 106 and the sensor identification information stored in the EEPROM 105 to the radio transmission / reception unit 102, whereby the biometric information modulated by the radio transmission / reception unit 102, the sensor identification. Information is transmitted and output from the antenna 17.

FIG. 7 is a circuit configuration diagram of the portable information terminal (watch) 2.
The portable information terminal 2 has a CPU 201 as a core, a clock signal generator 202 that generates and outputs a basic clock for timekeeping, a ROM 203 that stores programs and data, a work RAM 204, a liquid crystal screen, and the like. In addition to a display unit 205, an input unit 206 that outputs operation signals according to various button operations, a power supply circuit 207 including a battery, a radio wave transmission / reception unit 208 connected to the RFID antenna 22, and a wireless The transmission / reception control unit 209 performs transmission / reception of data to / from an external device by radio waves. Here, the CPU 201 monitors whether or not a predetermined measurement timing has been reached, and applies the battery voltage from the power supply circuit 207 to the radio wave transmission / reception unit 208 when it is detected that the measurement timing has been reached. Thus, power is supplied to the RFID antenna 22 so that sensor identification information and biological information are transmitted from the specimen adhesive sheet 1.

  The radio wave transmission / reception unit 207 transmits / receives information to / from the specimen adhesive sheet 1 by wireless radio waves. When sensor identification information and biological information transmitted from the specimen adhesive sheet 1 are received, the sensor identification information is received. The biological information is given to the CPU 201. The CPU 201 associates this sensor identification information with the biological information and stores them in the RAM 204. The transmission / reception control unit 209 transmits / receives information to / from a store server (not shown) installed in the store when newly purchasing the sample adhesive sheet 1 by using radio waves. The sensor identification information set in the adhesive sheet 1 is downloaded from the store server and is initially set in the RAM 204. Note that the initially set sensor identification information is used as authentication information for checking whether or not the proper specimen adhesive sheet 1 is attached at the time of biometric information measurement.

FIG. 8 is a diagram showing the contents of the measurement result table 23 provided in the portable information terminal 2.
This measurement result table 23 creates a measurement record each time sensor identification information and biological information are transmitted and output from the specimen adhesive sheet 1, and stores and manages the sensor identification information and biological information in association with each other. The measurement record includes items of “sensor ID”, “sensor type”, “measurement date / time”, “measurement value”, and “correction value”. “Sensor ID” indicates sensor identification information, and is ID information for identifying individual sensors. When a new specimen adhesive sheet 1 is attached to the specimen, the output from the specimen adhesive sheet 1 is output. The stored sensor ID is stored and managed.

  “Sensor type” is information indicating the type of sensor, and indicates the type of biosensor 16 such as a glucose sensor that detects glucose (blood glucose level), an odor sensor that detects odor, and the like. “Measurement date and time” is the reception date and time when the biological information is acquired from the specimen adhesive sheet 1, and “Measured value” is the biological information value acquired from the specimen adhesive sheet 1. The “correction value” is a correction value for correcting the biological information according to the elapsed time after the specimen adhesive sheet 1 is newly attached, and is a value automatically acquired from the correction value table 24 described later.

FIG. 9 is a diagram showing the contents of the correction value table 24 provided in the portable information terminal 2.
The correction value table 24 is set with correction values for correcting the biological information according to the elapsed time since the specimen adhesive sheet 1 was newly attached corresponding to the type of the biosensor 16. In general, a biosensor takes into account that the measurement accuracy deteriorates with time. Each correction value record has items of “sensor type”, “elapsed time since sensor replacement (minutes)”, and “correction data”, and the “elapsed time since sensor replacement” is determined by the specimen adhesive sheet 1. Elapsed time since newly installed, for example, 30 minutes, 60 minutes, 120 minutes, etc. are set corresponding to the sensor type (A), corresponding to the sensor type (B) 20 minutes, 45 minutes, 70 minutes, and so on are set. “Correction data” is a correction value for correcting the biological information in accordance with the elapsed time since the specimen adhesive sheet 1 was newly attached, and is set for each elapsed time. For example, the sensor type (A) “0” corresponding to 30 minutes later, “α1” corresponding to 60 minutes later, “α2” corresponding to 120 minutes later,...

FIG. 10 is a diagram showing the contents of the sensor setting table 25 provided in the portable information terminal 2.
This sensor setting table 25 is used when determining the type of sensor based on the content of the sensor ID, determining the measurement timing corresponding to the type of sensor, or determining the replacement time of the sensor. “Sensor type” is set corresponding to “Sensor ID range”, and “Measurement time interval” and “Sensor replacement time (minutes)” are set corresponding to this “Sensor type”. Yes. For example, when the sensor ID of 4 to 6 digits is “465”, (A) is set as the sensor type, and when the sensor ID is “879”, (B) is set as the sensor type. .

  Here, the sensor type automatically determined by referring to the sensor type table 25 is registered in the item “sensor type” of the measurement result table 23. “Measurement time interval” defines a measurement timing for measuring biological information, and for example, “60 minutes” is set corresponding to the type (A) of the sensor. The value of “measurement time interval” is arbitrary depending on the type of sensor. “Sensor replacement time (minutes)” indicates the elapsed time since the new specimen adhesive sheet 1 was attached, and when this time has elapsed, a warning message is displayed to prompt sensor replacement. It is made to output.

FIG. 11 is a view showing the contents of the sensor authentication table 26 provided in the portable information terminal 2.
The sensor authentication table 26 stores and manages sensor IDs that can be measured in advance. As described above, when the sample adhesive sheet 1 is newly purchased, the sensor authentication table 26 is downloaded from a store server installed in the store. The sensor ID is registered in the sensor authentication table 26. In this case, the sensor ID registered in the sensor authentication table 26 is compared with the sensor ID transmitted and output from the specimen adhesive sheet 1, and a sensor authentication process is performed to check whether the sensor ID is a valid sensor ID permitted in advance. By doing so, a third party other than the person wearing the specimen adhesive sheet 1 is prevented from using the portable information terminal 2 to steal biological information.

  Next, the operation concept of the portable information terminal 2 in this embodiment will be described with reference to the flowchart shown in FIG. Here, each function described in this flowchart is stored in the form of a readable program code, and operations according to the program code are sequentially executed. Moreover, the operation | movement according to the above-mentioned program code transmitted via the transmission medium can also be performed sequentially. In other words, in addition to the recording medium, an operation peculiar to this embodiment can be executed by using a program / data supplied externally via a transmission medium.

FIG. 12 is a flowchart showing a biological information measurement process that is started when a measurement start button (not shown) is operated on the portable information terminal 2 side.
First, the CPU 201 monitors the presence / absence of an operation of a measurement start button for instructing measurement start of biological information. When the measurement start button is operated, an initialization process is executed (step S1). Power supply to the RFID antenna 22 is started, and this electric power is transmitted and output as a radio wave from the antenna 22 (step S2).

  Now, for example, in a state where the specimen adhesive sheet 1 is mounted near the inside of the wrist, the electrical energy obtained by the radio waves received from the antenna 17 is accumulated in the accumulating unit 104 on the specimen adhesive sheet 1 side. Thus, the CPU 101, the radio wave transmitting / receiving unit 102, the EEPROM 105, and the measurement circuit 106 operate, and the measurement circuit 106 measures a change in the biological reaction detected by the biosensor 16 as biological information, and the CPU 101 is obtained by the measurement circuit 106. The biometric information and the sensor ID stored in the EEPROM 105 are transmitted and output.

  Here, on the portable information terminal 2 side, when the CPU 201 receives and acquires the sensor ID transmitted and output from the sample adhesive sheet 1 (step S3), the CPU 201 accesses the sensor authentication table 26 based on the sensor ID and permits it in advance. A sensor authentication process for authenticating whether or not the sensor ID is a regular sensor ID is executed, and it is checked whether or not the sensor ID is authorized in advance (step S4). If the sensor ID is not a regular sensor (NO in step S4), power supply to the RFID antenna 22 is stopped (step S5), and a warning message indicating that the sensor is not permitted is displayed (step S5). S6). Then, the biological information measurement process is terminated and the process proceeds to other processes.

  On the other hand, if it is determined that the sensor ID is authorized in advance (YES in step S4), it is checked whether the sensor ID received and acquired this time is a new sensor ID (step S7). That is, the measurement result table 23 is searched, the sensor ID received this time is compared with the sensor ID set in the measurement result table 23, and whether or not the sensor ID is a new sensor ID based on the match / mismatch is rephrased. In this case, it is checked whether or not a new specimen adhesive sheet 1 is attached to the specimen. Initially, since the sensor ID is not set in the measurement result table 23, it is determined in step S7 that they do not match. In this case, after the received sensor ID is set in the measurement result table 23 and stored and registered (step S8), an addition timer (not shown) for measuring the elapsed time since the new specimen adhesive sheet 1 is mounted is provided. A clear start is performed (step S9).

  Then, the CPU 201 receives and acquires the biological information transmitted and output from the specimen adhesive sheet 1 as a “measurement value” (step S10), and then stops feeding the RFID antenna 22 (step S11). Thereafter, the sensor setting table 25 is accessed based on the received and acquired sensor ID, the “sensor type” corresponding to the sensor ID is acquired, and the timer time counted by the above addition timer is acquired (step S12). ), By accessing the correction value table 24 based on the “sensor type” and “timer time”, the corresponding “correction value” is read out and acquired (step S13). Since the “timer time” is within 30 minutes immediately after the new specimen adhesive sheet 1 is mounted, “0” is read as the correction value.

  The current date / time is acquired as “measurement date / time”, and the “measurement date / time”, “sensor type”, “measurement value”, and “correction value” are set in the corresponding items of the measurement result table 23 (step S14). . In a state where the first measurement record is created and stored and managed in this way, the CPU 201 corrects the “measurement value” in the record based on the “correction value” (step S15). In this case, the correction method is arbitrary and varies depending on the type of sensor. For example, the correction may be performed by adding the “correction value” to the “measurement value”. After correcting the measured value in this way, the corrected measurement result is displayed and output as a transition graph (step S16). This graph display screen has been switched from the clock screen that displays the current date and time to the biological information display screen. In addition to the guidance display of the sensor type and timer time, the measurement results obtained at each measurement timing have elapsed over time. Is displayed and output as a transition graph (bar graph) corresponding to, but initially, only one measurement result is displayed.

  In step S17, the timer time is acquired, and the sensor setting table 25 is searched based on the “sensor type” to read out the corresponding “measurement time interval”. The “timer time” and the “measurement time interval” are read out. To determine whether the “timer time” has reached an integral multiple of the “measurement time interval”, that is, whether the measurement timing has been reached (step S18). Now, when the “timer time” reaches “60 minutes”, which is the “measurement time interval”, it is determined that the measurement timing has been reached. If the sensor ID received this time is a valid sensor ID that is permitted in advance (YES in step S4), it is checked whether it is a new sensor ID (step S7).

  Now, if the specimen adhesive sheet 1 is not exchanged, a sensor ID match is detected in step S7. Therefore, the process of step S8 for storing the sensor ID and the process of step S9 for clear-starting the timer are as follows: Each step is skipped, and the processing after step S10 is executed. Hereinafter, every time the measurement timing is reached, the above-described operation is repeated. Even when the measurement button is operated before the timer time reaches the measurement timing (NO in step S18) (YES in step S19), the process proceeds to step S2 and after each time the measurement button is operated. The above-described operation is performed. The measurement button is operated when measurement is performed at a timing other than when the measurement timing is set by the timer, or when the sample adhesive sheet 1 is attached to a part of the human body that the portable information terminal 2 cannot always detect. . When the specimen adhesive sheet 1 is attached to a part of the human body that the portable information terminal 2 cannot always detect, the portable information terminal 2 is positioned in the vicinity of the specimen adhesive sheet 1 and then the measurement button is operated.

  During such a measurement period, it is monitored whether the timer time has reached the “sensor replacement time” set in the sensor setting table 25 (step S20), and it is detected that the “sensor replacement time” has been reached. Then, the CPU 201 displays and outputs a warning message for prompting sensor replacement (step S21). Further, the CPU 201 checks whether or not a measurement end button (not shown) is operated (step S22). If the measurement end button is not operated, the process proceeds to step S17, and the above-described operation is subsequently performed. .

  As a result, when the specimen adhesive sheet 1 is replaced by peeling off the currently attached old specimen adhesive sheet 1 and attaching a new specimen adhesive sheet 1 of the same type, this is detected in step S7. Then, the process proceeds to step S8. In addition to the ID of the old sensor that has been mounted so far, the ID of the newly mounted sensor is set in the measurement result table 23, and the timer is cleared and started (step S9). ), The above operation is repeated. As a result, the measurement results obtained by the old specimen adhesive sheet 1 and the new specimen adhesive sheet 1 are stored and managed in the measurement result table 23 as continuous information. If the measurement end button is operated during the measurement period (YES in step S22), the biological information measurement process is terminated and the process proceeds to other processes.

  As described above, in this embodiment, the specimen pressure-sensitive adhesive sheet 1 is provided with the pressure-sensitive adhesive layer 14 on one side of the thin film substrate 13, the peelable layer 15 that is detachably bonded to the pressure-sensitive adhesive layer 14, and the pressure-sensitive adhesive layer. The biosensor 16 and the RFID 18 are arranged between the sensor 14 and the release layer 15, and the sensor ID set in the RFID 18 and the biological information obtained by the biosensor 16 are transmitted and output. The portable information terminal 2 that performs a transmission / reception operation with respect to 1 transmits and outputs a signal from the RFID 18 in a state where the sample adhesive sheet 1 is adhered to the sample by the adhesive layer 14 by peeling off the release layer 15 of the sample adhesive sheet 1. The received sensor ID and biometric information are received, the sensor ID and the biometric measurement value are stored in association with each other, and the biometric measurement value is proposed. Since the output is made possible, the specimen adhesive sheet 1 and the portable information terminal 2 can be separated from each other, and the specimen adhesive sheet 1 only needs to be attached to the skin of a human body. It is possible to measure biological information. In this case, even if the sample adhesive sheet 1 and the portable information terminal 2 are separated, the portable information terminal 2 carelessly stores and manages the sensor ID and the measured value in association with each other. Even if it peels off or is replaced with a new specimen adhesive sheet 1, the correspondence between the sensor and the measurement result can be maintained, and the biological information can be accurately measured.

In this case, since the thin film substrate 13 of the specimen adhesive sheet 1 is made of a flexible film member so that it can be attached to a curved specimen, the specimen adhesive sheet can be attached to any part of the human body. It can be installed securely.
Further, the RFID 18 in the specimen adhesive sheet 1 accumulates electric energy of received radio waves received by the antenna, and transmits and outputs a sensor ID and biological information using this accumulated energy. The battery can be made unnecessary by the technology, and the specimen pressure-sensitive adhesive sheet can be reduced in size and thickness.

  On the other hand, the portable information terminal 2 has an RFID antenna 22 that transmits and receives radio waves to and from the specimen adhesive sheet 1 and monitors whether or not a predetermined measurement timing has been reached. When it is detected that the measurement timing is reached, the sensor ID and the biological information are transmitted and output from the specimen adhesive sheet 1 by supplying power to the antenna 22, so that power consumption can be suppressed as much as possible. In other words, the built-in battery can have a long service life, and is highly practical.

  The portable information terminal 2 determines whether or not a new sample adhesive sheet 1 is mounted based on whether or not a new sensor ID is received, and when the new sample adhesive sheet 1 is mounted, Since the elapsed time since the specimen adhesive sheet 1 is mounted is measured and the biometric value at the time of the correction is corrected with the correction value corresponding to the elapsed time, the enzyme constituting the biosensor 16, etc. Even if the biological material is deteriorated due to the change over time, the influence can be prevented and the biological information can always be measured accurately.

  Here, the type of the biosensor 16 is determined based on the received sensor ID, and the biological information is corrected with a correction value corresponding to the type of the biosensor. The influence can be corrected for each type of sensor. Further, when the same type of sensor is newly installed instead of the currently installed biosensor 16 and the sensor is exchanged, it is obtained by the previously installed sensor and the newly installed sensor. Since the measured biometric values are stored and managed as continuous information, even if the specimen adhesive sheet 1 is inadvertently peeled off or replaced with a new specimen adhesive sheet 1, the correspondence between the sensor and the measurement result Attaching can be maintained, and biological information can be accurately measured.

  Each time the portable information terminal 2 receives a sensor ID, the portable information terminal 2 determines whether or not it is a normal biosensor by comparing the received sensor ID with preset sensor identification information. Since the biometric value is stored and managed in correspondence with the sensor ID on the condition that the sensor is determined to be a sensor, for example, a third party other than the person wearing the sample adhesive sheet 1 It is possible to effectively prevent the biometric measurement value from being read and read using the portable information terminal 2, and it is possible to perform secure security management of the personal information called biometric information.

The portable information terminal 2 determines whether or not a new sample adhesive sheet 1 is mounted based on whether or not a new sensor ID is received, and when the new sample adhesive sheet 1 is mounted, The elapsed time since the specimen adhesive sheet 1 is attached is counted, and when it is detected that the elapsed time has reached a predetermined sensor replacement time, the current specimen adhesive attached to the specimen is detected. Since the fact that the sheet should be replaced is notified, it is possible to immediately know the replacement time of the specimen adhesive sheet, and more accurate measurement is possible.
Further, since the portable information terminal 2 displays the transition state in a graph based on a plurality of biometric measurement values stored and managed in association with the same sensor ID, for example, the maximum value 1 It is possible to know not only one measurement result but also a measurement value that changes over time.

In the above-described embodiments, the specimen adhesive sheet 1 is attached to the inside of the vicinity of the wrist, but the attachment site is arbitrary, and may be, for example, an earlobe. Moreover, although the enzyme sensor was illustrated as the biosensor 16, it is applicable similarly even if it is another biosensor.
In the above-described embodiment, the transition graph indicating the change of the biological measurement value with time is displayed, but the standard value may be displayed together. Further, a warning sound may be generated and output when an abnormality occurs.

In the above-described embodiment, the clock display screen that displays the current date and time is switched to the graph display screen that displays the biological information. However, the clock display screen and the graph display screen are displayed together on the same screen. You may do it.
Further, in the above-described embodiment, the case where the portable information terminal 2 is a digital display type wristwatch is illustrated, but it may be a pointer type wristwatch having a liquid crystal display unit, and is not limited to a wristwatch. It may be a portable information device such as a mobile phone or a PDA, and may of course be a portable device dedicated to biometric information measurement.

  On the other hand, a recording medium (for example, a CD-ROM, a flexible disk, a RAM card, etc.) on which program codes for executing the above-described units are recorded may be provided to the computer. That is, a recording medium having a computer-readable program code, which is provided with an adhesive layer on one side of a thin film substrate, a release layer that is releasably adhered to the adhesive layer, and peeling from the adhesive layer Sensor identification information set in the electronic tag and biological information obtained by the biosensor in a state where a thin specimen adhesive sheet in which a biosensor and an electronic tag are arranged between the layers is adhered to the specimen. A function of receiving the sensor identification information and the biological information when it is transmitted and output from the specimen adhesive sheet side, a function of storing and managing the received sensor identification information and the biological information in association with each other, and storage management are performed. A computer-readable recording medium that records a program for realizing the function of outputting biometric information may be provided.

The external view which showed the state which mounted | wore the human body arm with the sample adhesive sheet 1 and the portable information terminal 2. FIG. (A) is an overall side view of the specimen pressure-sensitive adhesive sheet 1, and (B) is an enlarged cross-sectional view of the main part of the specimen pressure-sensitive adhesive sheet 1. The figure at the time of removing the peeling layer 15 and the intermediate | middle protective layer 19 from the sample adhesive sheet 1, and seeing the whole sample adhesive sheet from the back side (sample side). (A) is a side view of the RFID 18, and (B) is a rear view thereof. The external appearance front view of portable information terminal (watch) 2. FIG. The figure which showed the circuit structure of RFID18. The circuit block diagram of the portable information terminal (watch) 2. FIG. The figure which showed the content of the measurement result table 23 provided in the portable information terminal 2. FIG. The figure which showed the content of the correction value table 24 provided in the portable information terminal 2. FIG. The figure which showed the content of the sensor setting table 25 provided in the portable information terminal. The figure which showed the content of the sensor authentication table 26 provided in the portable information terminal 2. FIG. The flowchart which showed the biometric information measurement process started execution when the measurement start button was operated in the portable information terminal 2 side.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Specimen adhesive sheet 2 Portable information terminal 13 Thin film substrate 14 Adhesive layer 15 Peeling layer 16 Biosensor 17 Antenna 18 Electronic tag (RFID)
22 RFID antenna 23 Measurement result table 24 Correction value table 25 Sensor setting table 26 Sensor authentication table 101, 201 CPU
102 Radio wave transmission / reception unit 104 Storage unit 105 EEPROM
106 measurement circuit 206 input unit 207 power supply circuit 208 radio wave transmission / reception unit

Claims (11)

A biological information measuring device that measures biological information using a biosensor that detects a change in a biological reaction on a membrane on which a biological substance is immobilized,
An adhesive layer is provided on one side of the thin film substrate, and a release layer that is releasably adhered to the adhesive layer is provided, and the biosensor and the electronic tag are disposed between the adhesive layer and the release layer. A specimen adhesive sheet for transmitting and outputting sensor identification information set in the electronic tag and biological information obtained by the biosensor;
A receiving means for receiving the sensor identification information and biological information transmitted and output in a state in which the specimen adhesive sheet is adhered to the specimen by the adhesive layer by peeling off the peeling layer constituting the specimen adhesive sheet; A portable information terminal having information storage means for storing and managing sensor identification information and biometric information in association with each other, and output means for outputting the contents of the information storage means;
A biological information measuring device comprising:   2. The biological information measuring apparatus according to claim 1, wherein the thin film substrate of the specimen adhesive sheet is configured by a flexible film member so that the specimen adhesive sheet can be attached to a curved specimen. The electronic tag in the specimen pressure-sensitive adhesive sheet is an RFID tag with an antenna, accumulates electric energy of received radio waves received by the antenna, and transmits and outputs the sensor identification information and biological information using the accumulated energy. ,
2. The biological information measuring device according to claim 1, wherein the biological information measuring device is configured as described above. The portable information terminal has an antenna that transmits and receives radio waves to and from the specimen adhesive sheet, and has monitoring means for monitoring whether or not a predetermined measurement timing has been reached.
When it is detected that the measurement timing has been reached, sensor identification information and biological information are transmitted and output from the specimen adhesive sheet by supplying power to the antenna.
4. The biological information measuring apparatus according to claim 1, wherein the biological information measuring apparatus is configured as described above. The portable information terminal is
Correction value storage means for storing a correction value for correcting biological information for each elapsed time after the specimen adhesive sheet is newly attached;
A discriminating means for discriminating whether or not a new specimen adhesive sheet is attached based on whether or not new sensor identification information has been received;
When it is determined that a new sample adhesive sheet is mounted by the determining unit, a time measuring unit that measures an elapsed time since the sample adhesive sheet is mounted;
A correction unit that reads out a correction value corresponding to the elapsed time obtained by the time measuring unit from the correction value storage unit and corrects the biological information at the time;
5. The biological information measuring device according to claim 1 or 4, characterized by comprising: The correction means determines the type of biosensor based on the received sensor identification information and corrects biological information with a correction value according to the type of biosensor.
The living body information measuring apparatus according to claim 5, which is configured as described above. When the same type of sensor is newly installed instead of the currently installed biosensor and the sensor is replaced, the living body obtained by the sensor that has been installed and the newly installed sensor Storing and managing information as continuous information,
The biological information measuring apparatus according to claim 1, wherein the biological information measuring apparatus is configured as described above. Each time the portable information terminal receives sensor identification information, the portable information terminal compares the received sensor identification information with preset sensor identification information to determine whether the portable information terminal is a legitimate biosensor. The biometric information is stored and managed in correspondence with the sensor identification information on the condition that the discrimination means determines that the biosensor is a regular biosensor.
The biological information measuring apparatus according to claim 1, wherein the biological information measuring apparatus is configured as described above. The portable information terminal is
A discriminating means for discriminating whether or not a new specimen adhesive sheet is attached based on whether or not new sensor identification information has been received;
When it is determined that a new sample adhesive sheet is mounted by the determining unit, a time measuring unit that measures an elapsed time since the sample adhesive sheet is mounted;
Informing means for notifying that the current specimen adhesive sheet attached to the specimen should be replaced when it is detected that the elapsed time obtained by this timing means has reached a predetermined sensor replacement time. When,
The biological information measuring device according to claim 1, wherein: The output means displays a graph of the transition state based on a plurality of biological information stored and managed in association with the same sensor identification information in the information storage means.
The biological information measuring apparatus according to claim 1, wherein the biological information measuring apparatus is configured as described above. Against the computer,
A thin specimen in which an adhesive layer is provided on one side of a thin film substrate, a release layer adhered to the adhesive layer in a peelable manner is provided, and a biosensor and an electronic tag are disposed between the adhesive layer and the release layer When the adhesive sheet is adhered to the specimen, the sensor identification information set in the electronic tag and the biological information obtained by the biosensor are transmitted and output from the specimen adhesive sheet side. A function of receiving biological information;
A function of storing and managing the received sensor identification information and biological information in association with each other;
A function for outputting biometric information stored and managed;
A program to realize

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