JPH10328170A - Blood sugar monitoring system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blood sugar monitoring system which has non-invasion property without conventionally forced pains and enables monitoring at all the time as well. SOLUTION: This system is composed of a sensor part 12 mounted on a body 11 such as a finger and a data processing part 13 connected to that sensor part, and data detected at the sensor part 12 are analyzed while referring to a data base composed of the medical data, which are stored in a storage part inside the data processing part 13, of subject in the past. Thus, blood sugar can be appropriately and exactly monitored rather than conventional cases. Such a monitoring system 10 is equipped with a network function as well and a caution to a person related to medical affairs or the reagent himself is issued as needed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for monitoring physical data, in particular, a blood glucose level. More specifically, the present invention relates to a non-invasive blood glucose monitoring system for diabetics and others requiring blood glucose management.

[0002]

2. Description of the Related Art Due to aging and changes in lifestyle, the number of subjects who want to control blood sugar levels is rapidly increasing. At the time of conventional blood glucose measurement, for example, puncture a finger with a measuring needle to collect blood,
There are devices that measure blood glucose levels by bringing the device into direct contact with blood. However, many of the subjects feel painful in sticking a needle into their finger. In addition, it is difficult to accurately measure a blood glucose level that fluctuates greatly due to the elapsed time after a meal, etc., by using only time-limited measurement by collecting blood from a finger. It is also difficult to determine the effect.

[0003] Further, since blood collection from a finger is both local and temporary, it is not possible to know fluctuations in blood sugar level over time. For example, even if the blood glucose level deviates from the normal range, it is not known whether the deviation has occurred slowly or rapidly in the above-described method. That is, in the above-described conventional measuring device, the blood glucose level is constantly monitored, and the abnormality is not automatically detected when the blood glucose level deviates from the normal range for the subject.

[0004]

SUMMARY OF THE INVENTION In view of the above-described circumstances surrounding the conventional blood glucose measuring device, the present invention eliminates the need for the conventional invasive detection of blood glucose levels.
An object of the present invention is to eliminate the disadvantages of the conventional blood glucose measurement using only spot measurement. The blood sugar level greatly fluctuates depending on the elapsed time after a meal, components and amounts of food and drink, and the like.
Therefore, the conventional detection only at the spot (one time point) is not enough to know the temporal change of the blood glucose level. It is an object of the method and apparatus according to the present invention to prevent the subject's body from being disturbed by monitoring the blood glucose level constantly over time.
Furthermore, with the device according to the invention, the monitoring of the blood glucose level is carried out non-invasively, so that the psychological and physical pain and burden on the participant's side are minimized.

[0005]

According to the present invention, data which is attached to a part of the body of a person to be monitored for blood sugar and includes a light emitting part and a light receiving part and which indicates the blood sugar level of the subject is detected. A sensor unit, a data processing unit that analyzes and calculates the blood sugar level of the subject based on optical data transmitted from the sensor unit using a built-in microprocessor that controls the sensor unit and analyzes data received by the light receiving unit, A storage unit storing a database composed of physical data including blood glucose levels of the subject for a certain period in the past, and a storage unit storing the database. Further, the data processing unit in the system includes means for comparing the calculated blood glucose level with data in the body data database of the storage unit, and the blood glucose level calculated based on the comparison of the data is applied to the body of the subject. Means for determining the effect to be obtained and means for instructing to issue a warning signal when the determined physical effect exceeds a predetermined critical level to be determined to be medically dangerous.

The warning signal can be communicated, for example, via wireless communication to a medical and health service representative at a medical institution that is central to a medical network in the area where the subject resides. Of course, the subject himself / herself can know his / her own blood sugar information by the display on the display provided in this system. If the blood sugar level abnormality is known early, it is possible to perform a treatment for returning blood sugar to normal at an early stage. Abnormal blood glucose levels can cause serious injury to the human body, but the blood glucose monitoring system according to the present invention can prevent it.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a conceptual diagram of the entire blood glucose monitoring system 10 according to the present invention. The monitoring system 10 of the present invention includes a sensor unit 12 attached to a living body 11 and a data processing unit 13 connected to the sensor unit 12. In the embodiment shown in FIG.
The sensor unit 12 is mounted on the finger 11 of the monitoring subject. The body part may also be the ear (eg, the outer ear). The data processing unit 13 includes a microprocessor, and the data detected by the sensor unit 12 is:
The data is analyzed by the data processing unit 13 to calculate a blood sugar level. Next, the blood glucose level data of the subject is compared with the past blood glucose level data to determine whether the blood glucose level is abnormal or normal, and a caution signal or a warning signal is transmitted as necessary.

The data processing unit 13 is configured to be able to communicate via a wireless communication network with a center system 30 installed between medical devices in the area. Make a report.

FIG. 2 illustrates the sensor unit 12 of the blood glucose monitoring system 10 of the present invention and the data processing unit 13 connected thereto in more detail. Components common to FIG. 1 are denoted by the same reference numerals. The sensor unit 12 is mounted on a finger 11 of a hand, which is a part of the body of the blood glucose monitoring subject, and includes a light emitting unit 14 and a light receiving unit 15.

The data processing unit 13 includes a central processing unit (CPU) 18 which is a microprocessor, and a light emission control unit 16.
Light receiving control unit 17, storage unit 19, communication unit 20,
It includes a display unit 21 and an emergency sound generation unit 22. Further, the data processing unit 13 has an appropriate interface such as an optical fiber between the data processing unit 13 and the sensor unit 12. The connection between the data processing unit 13 and the sensor unit is made of a material having appropriate flexibility.

The operation of the blood glucose monitoring system 10 according to the embodiment shown in FIG. 2 will be described in order. The light emitting unit 14 responds to a command from the CPU 18 of the data processing unit 13 and, under the control of the light emission control unit 16, emits a light beam containing light having a wavelength ranging from the ultraviolet region to the infrared region to the sensor unit 1.
2 radiates into the inside of the finger 11 mounted. The light beam transmitted through the finger 11 is received by the light receiving unit 15 located on the opposite side of the finger, and reaches the light receiving control unit 17 via the optical fiber path. The light reception control unit 17 analyzes the spectrum of the received light flux, and uses a built-in optical sensor and an AD converter as light reception amount data for each wavelength having a small width to obtain C
Send to PU18.

The CPU 18 analyzes light reception data for each wavelength received from the light reception control unit 17, and analyzes components in blood from the wavelength and the amount of light absorbed while the light passes through the finger 11. , Calculate the blood glucose level as one of the components. The processes of light emission, light reception, and analysis described above are repeatedly executed.

The blood sugar level calculated as described above is compared with the subject's past blood sugar level data stored in the storage unit 19. If the currently detected blood sugar level is out of the normal range, or if the blood sugar level is out of the preset range within a preset time, a caution signal is issued. The information is transmitted via the communication unit 20 to the center system 30 installed between the medical devices that are the core of the medical network in the area. The information is also transmitted to the person visually on the display unit 21 and voiced by the emergency sound generation unit 22. The display unit 21 displays both the normal blood glucose level of the patient and the currently detected blood glucose level.

The blood glucose monitoring system 10 of the present invention
The detection of blood glucose level by, such as temporary, continuous, or intermittent, as selectively performed from any timing,
The data processing unit 13 can be set in advance. When performing continuous or intermittent blood glucose monitoring, the abnormal state of the blood glucose level fluctuation over time is compared with the past blood glucose level fluctuation of this subject in the physical data database of the storage unit 19. This determines if the ongoing fluctuations in blood glucose levels are medically dangerous. A warning is issued if necessary.

Various mechanisms can be considered for the sensing mechanism in the sensor unit 12 of the blood sugar monitoring system 10. Specifically, the sensor unit 12 can further include a unit for detecting a vital sign of the subject other than the blood glucose level such as a pulse wave, arterial oxygen saturation (SpO ₂ ), hematocrit, and body temperature. . In that case, the blood glucose level can be calculated indirectly using one or more vital signs other than these blood glucose levels.
By comparing the blood glucose level calculated by a direct method such as spectral analysis of light passing through the finger as described above with the blood glucose level calculated indirectly by another method, at multiple time points From the detected blood sugar levels,
The most appropriate blood sugar level can be selected. Also,
In the case of blood glucose levels detected in spots, the accuracy can also be improved using one or more detected vital signs.

The light emitting section 14 of the sensor section 12 is configured to vary the wavelength of emitted light with time, so that the sensor section 12 can detect a plurality of vital signs with only one sensor. it can. Since the sensor unit 12 is directly attached to a body such as a finger, it must be small, and it is difficult to provide a plurality of sensors. It is preferable to configure the system so that various settings can be made by using the setting 18. Specifically, for example, the microprocessor 18 can be configured as an application-specific integrated circuit (ASIC) in which the functions of the blood glucose monitoring system of the present invention are fully incorporated.

The sensor unit 12 of the blood sugar monitoring system 10 has a sensor for detecting bias (disturbance) data in addition to a sensor for measuring blood sugar, and a data processing unit analyzes a difference between the bias data. By doing so, the accuracy of the already calculated blood sugar level can be improved. Further, the sensor unit 12 includes a light emitting unit that generates light including a wavelength range from ultraviolet light to infrared light, and a light detection element that separates and detects light in each wavelength range,
The data processing unit 13 can calculate the blood sugar level of the subject based on the data of the light intensity for each of the plurality of wavelength ranges separated and detected by the light receiving unit. Further, the sensor unit 12 may include a unit that emits light while continuously changing light in a wavelength range from ultraviolet rays to infrared rays. The data processing unit 13 determines the wavelength of the light detected by the sensor unit 12 and Based on the intensity, the blood glucose level can be calculated while excluding the effects of other contained substances in the blood of the subject.

[0018]

According to the system of the present invention, the blood glucose level can be measured not only temporarily, but also continuously or intermittently and easily over time. This makes it possible to collect blood glucose data in chronological order, and analyzes the collected data with reference to information retrieved from a database that stores the past measurement data of the person. More accurate measurement than the blood glucose monitoring system.
With the accurate and multifaceted measurements thus obtained,
An early and accurate medical response is possible, and physical disability due to abnormal blood sugar levels can be avoided.

The non-invasive monitoring enables the subject to easily measure the blood glucose level by himself without experiencing any psychological or physical pain or resistance. This is a remarkable effect. Since the system of the present invention has a network function and can exchange information with a medical institution or the like in the area, not only personal closed use but also open use for the network is possible. Can also be realized. Further, for example, considering the link between the personal computer provided in the home of the person to be monitored and the monitoring system of the present invention, it is possible to utilize the processing capacity and the large capacity of the storage device of the personal computer. In addition, the limitation of the processing capacity and the storage capacity due to the purpose that the system of the present invention to be worn on the body inherently accepts is eliminated. The construction of these networks, as is known to those skilled in the art, is based on the above-mentioned effects achieved by the blood glucose monitoring system according to the present invention, by superimposing the recent advances in network technology. A monitoring system having a remarkable effect that has not been achieved in the past can be realized.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a blood glucose monitoring system according to the present invention.

FIG. 2 is a block diagram showing a more detailed configuration of the blood glucose monitoring system according to the present invention.

[Explanation of symbols]

Reference Signs List 10 blood sugar monitoring system 11 living body (one part of body of blood sugar monitoring target person) 12 sensor unit 13 data processing unit 14 light emitting unit 15 light receiving unit 16 light emitting control unit 17 light receiving control unit 18 CPU (microprocessor) 19 storage unit 20 communication Unit 21 Display unit 22 Emergency sound generation unit 30 Center system (system placed in medical institutions, etc.)

Claims (14)

[Claims] 1. A sensor unit mounted on a part of the body of a subject for blood glucose monitoring and including a light emitting unit and a light receiving unit for detecting data indicating a blood sugar level of the subject, and controlling the sensor unit. Using a built-in microprocessor that analyzes data received by the light receiving unit, based on optical data transmitted from the sensor unit, a data processing unit that analyzes and calculates the blood glucose level of the subject, A storage unit storing a database composed of physical data including blood glucose levels for a certain period in the past, wherein the data processing unit stores the calculated blood glucose level in a physical data database of the storage unit. Means for comparing the calculated blood glucose level based on the comparison of the data with the subject's body. And a means for instructing to issue a warning signal when the determined physical effect exceeds a predetermined critical level to be determined to be medically dangerous. Blood glucose monitoring system. 2. The blood glucose monitoring system according to claim 1, wherein the sensor unit and the data processing unit include:
A blood glucose monitoring system, which can be worn on a part of the subject's body including a finger and a wrist. 3. The blood glucose monitoring system according to claim 1, wherein the microprocessor detects a blood glucose level by the sensor unit such that the sensor unit detects the blood glucose level temporarily, continuously, or intermittently. Blood glucose monitoring system characterized by controlling the blood glucose. 4. The blood glucose monitoring system according to claim 1, wherein when the sensor unit performs continuous or intermittent blood glucose monitoring, the abnormal state in the fluctuation of the blood glucose level over time is stored. Means for determining based on a comparison with past blood glucose level fluctuations in the body data database of the part, and warning when the determined fluctuation in blood glucose level exceeds a predetermined critical level to be judged to be medically dangerous Means for commanding to emit a signal.
system. 5. The blood glucose monitoring system according to claim 1, wherein the data processing unit extracts a blood glucose level detected at a plurality of time points, the most appropriate blood glucose level in the constantly changing arterial blood flow. A blood glucose monitoring system, further comprising means. 6. The blood glucose monitoring system according to claim 1, wherein the sensor unit includes one of vital signs other than blood glucose level including pulse wave, arterial oxygen saturation (SpO ₂ ), hematocrit, and body temperature. Means for detecting one or more vital signs, wherein the data processing unit indirectly calculates a blood glucose level using the detected one or more vital signs,
Means for improving the accuracy of the blood glucose level already directly calculated by using the detected one or more vital signs. 7. The blood glucose monitoring system according to claim 6, wherein the data processing unit changes a wavelength of light emitted by the means for detecting the one or more vital signs included in the sensor unit with respect to time. The blood glucose monitoring system according to claim 1, further comprising: means for detecting a plurality of vital signs by a single sensor. 8. The blood glucose monitoring system according to claim 1, wherein the sensor unit includes a sensor for detecting bias (disturbance) data in addition to a sensor for measuring blood glucose, and the data processing unit includes: A blood sugar monitoring system, further comprising means for improving the accuracy of a blood sugar level already calculated by analyzing a difference between the bias data. 9. The blood glucose monitoring system according to claim 1, wherein the data processing unit has means for generating a visual or audible warning based on the warning signal, and an interface with the data processing unit. Means for sending an alert to a medical institution via a network;
A blood glucose monitoring system comprising: 10. The blood glucose monitoring system according to claim 1, wherein the sensor unit separates and detects light in each wavelength range from a light emitting unit that generates light including a wavelength range from ultraviolet rays to infrared rays. A light receiving unit having a light detecting element, wherein the data processing unit calculates the blood glucose level of the subject based on data of light intensities in a plurality of wavelength ranges separated and detected by the light receiving unit. A blood glucose monitoring system, further comprising means. 11. The blood glucose monitoring system according to claim 1, wherein the sensor unit includes a unit that emits light while continuously changing light in a wavelength range from ultraviolet rays to infrared rays, and the data processing unit includes: Blood glucose level calculating means for calculating a blood glucose level based on the wavelength and intensity of light detected by the light receiving section of the sensor section while eliminating the influence of other contained substances in the blood of the subject. Monitoring system. 12. The blood glucose monitoring system according to claim 1, wherein the light emitting unit includes a unit that emits light in a wavelength range from ultraviolet rays to infrared rays, and wherein the data processing unit includes a body of the subject. A blood glucose monitoring system, further comprising means for spectrally decomposing light transmitted through a part and detected by the light receiving unit to calculate light absorption for each wavelength. 13. The blood glucose monitoring system according to claim 1, wherein the data processing unit is currently detected based on a comparison with past data on a blood component of the subject in the physical data database. A blood glucose monitoring system, further comprising: means for improving the accuracy of a blood glucose level value detected by analyzing a change in data. 14. A computer-readable storage medium storing a computer program for executing the function of the blood glucose monitoring system according to any one of claims 1 to 13. .