KR100590290B1 - Blood sugar management system - Google Patents

Abstract

The present invention relates to a blood sugar management device capable of measuring blood sugar and exercise amount in one device. The blood sugar management device has a sensor strip insertion hole,

A power supply for supplying power to the electrode of the blood sugar measurement sensor strip; A current sensing unit for detecting an amount of current flowing through the electrode; A motion detector for detecting a motion; A control unit for reading out a blood sugar value corresponding to the detected current amount from a memory and outputting it to a display unit or calculating an exercise amount of a user from a signal output from the motion detection unit and outputting it to the display unit; And a key operation unit for setting a blood sugar measurement mode and an exercise amount measurement mode.

Momentum, blood sugar, self-treatment.

Description

Blood glucose management communication terminal and blood sugar management system {BLOOD SUGAR MANAGEMENT SYSTEM}

1 is a block diagram of a blood sugar managing device according to a first embodiment of the present invention.

FIG. 2 is a circuit diagram of the current sensing unit 14 shown in FIG. 1.

3 is a view for explaining that the blood sugar management apparatus 10 according to the second embodiment of the present invention is used in combination with the communication terminal 30.

4 is a block diagram of a communication terminal 30 connected to the blood sugar managing apparatus 10 shown in FIG. 3.

Figure 5 is a block diagram of a blood sugar management communication terminal 50 according to a third embodiment of the present invention.

Figure 6 is a block diagram of a blood sugar management system according to an embodiment of the present invention.

The present invention relates to a blood sugar management system, and more particularly to a blood sugar management communication terminal capable of measuring blood glucose and exercise amount, and a blood sugar management system including them.

Diabetes is the most common non-communicable chronic disease in modern people, with sugar in the urine. There is a mixture of sugar in the blood, which we call blood sugar. Diabetes is the result of too much blood sugar flowing out into the urine. Normally, healthy people rarely excrete glucose in the urine. In diabetics, sugar (glucose) ingested through meals is not properly stored in liver, muscle, or fat cells, and accumulates in the blood. Therefore, in the case of diabetic patients maintain a much higher blood sugar than normal people, excessive amounts of blood sugar damage the renal glomeruli, sugar is passed through as it is excreted in the urine. So diabetics are in abnormal starvation. No matter how much you eat, you can't get enough nutrition.

Currently, about 5.5% (2.6 million) of the diabetic patients are out of Korea's total population, and about 1.3 trillion dollars are spent on diabetes medical expenses per year. It is reported that from 11.8 to 22 people in 2002.

Although the mortality rate due to diabetes and its complications is on the increase, the reason why the prevention and treatment is not efficiently performed is because of the disadvantage of the existing blood glucose meter.

First of all, in order to effectively treat diabetes and prevent complications, it is essential to provide comprehensive information for self-treatment such as diet, exercise, and weight management. However, since the existing blood glucose meter is designed as a stand-alone structure, it is simply measured. It is possible only to provide comprehensive information or request to provide comprehensive information as illustrated.

In addition, when using an existing blood glucose meter, it is inconvenient to record the blood glucose measurement result manually in a diabetic notebook. In order to receive a diagnosis of a specialist based on the measurement data, a remote medical treatment is required because the patient must visit a hospital and present the measurement data. There are disadvantages that are impossible.

Accordingly, an object of the present invention is to overcome the technical limitations of the existing blood glucose meter, and a blood sugar management communication terminal capable of inducing the blood glucose measurement as well as measuring the exercise amount of a diabetic patient affecting the blood sugar level to manage blood sugar by itself. In providing.

Furthermore, another object of the present invention is to provide a blood sugar management communication terminal capable of transmitting the measured blood glucose level and exercise information to a remote server,

Furthermore, it provides a blood sugar management system that can provide diabetic patients with blood sugar self-management information such as exercise recommendation data, diet, exercise therapy, and weight management according to blood sugar level.

Blood sugar management device according to an embodiment of the present invention for achieving the above object is formed with an insertion hole that can be inserted into the sensor strip,

A power supply for supplying power to the electrode of the blood sugar measurement sensor strip;

A current sensing unit for detecting an amount of current flowing through the electrode;

A motion detector for detecting a motion;

A control unit for reading out a blood sugar value corresponding to the detected current amount from a memory and outputting it to a display unit or calculating an exercise amount of a user from a signal output from the motion detection unit and outputting it to the display unit;

By including a key operation unit for setting the blood glucose measurement mode and the exercise amount measurement mode, the user himself measures his or her blood sugar as well as measures the amount of exercise can self-manage their own blood sugar.

On the other hand blood sugar management system according to an embodiment of the present invention,

A portable communication terminal for wirelessly transmitting the blood sugar value to a designated remote server by calculating the amount of exercise of the user from the blood sugar value obtained by detecting the current flowing through the sensor strip electrode inserted into the sensor strip insertion hole and the data obtained through the motion detector. Wow;

And a blood sugar managing server configured to store and manage blood sugar values of members transmitted from the portable communication terminal.

Considering the configuration of the blood sugar management system, a diabetic patient can measure his or her blood sugar and exercise amount through a communication terminal anytime, anywhere, and transmit the measured data to a remote place through a portable communication terminal, and manage the blood sugar located at a remote place. Receiving the blood sugar self-management information corresponding to the measured blood sugar level from the server has a feature that the patient himself can adjust the blood sugar.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

FIG. 1 is a block diagram of a blood sugar managing device 10 according to a first embodiment of the present invention, and FIG. 2 illustrates a circuit of the current sensing unit 14 shown in FIG.

Referring to FIG. 1, first, the power supply unit 12 supplies power to the electrode of the blood sugar measuring sensor strip S coupled to the sensor strip S insertion hole, and the current sensing unit 14 It is configured as shown in Figure 2 serves to detect the amount of current flowing in the working electrode formed on the sensor strip (S). The power supply 12 is a direct current voltage source.

For reference, the sensor strip S may also be called a bio sensor, as is already known as a sensor for measuring blood glucose. As an example, as shown in FIG. 2, the lead strip S4 corresponding to the number of electrodes is formed at one end of the electrically insulating substrate as shown in FIG. 2. These lead terminals S4 are connected to the electrodes S1, S2, S3 through lead wires, respectively.

Reference numeral S1 is a reference electrode, and reference numerals S2 and S3 are working electrodes. These electrodes serve to detect the amount of current generated during the oxidation or reduction of the electron acceptor in the enzyme reaction layer. Since the enzyme reaction layer contains enzymes and electron acceptors that react with the injected blood, the controller 16 to read the amount of current generated when the electron acceptor is oxidized or reduced can be read.

The above-described sensor strip S may assume a biosensor having one working electrode and a reference electrode. Exemplary sensor strips correspond to well-known conventional techniques that are well known in the art, and thus a detailed description thereof will be omitted below.

Referring back to FIG. 1, the motion detector 18 detects a motion of the blood sugar managing apparatus 10 and outputs it to the controller 16, and the controller 16 manages blood sugar based on control program data stored in an internal memory. Overall control of the operation of the device.

For example, the controller 16 reads the blood sugar value corresponding to the amount of current detected by the current detector 14 from the internal memory and displays it on the display unit 22 or from data output from the motion detector 18. Calculates the amount of exercise to display on the display unit 22.

The motion detector 18 may be implemented as a vibration sensor that detects vibration, such as a pedometer. In this case, the controller 16 may calculate the amount of exercise of the user by counting the number of vibrations detected by the vibration sensor.

If the motion detector 18 detects the geomagnetism and outputs the current orientation information, the controller 16 may calculate a user exercise amount by counting a change in the orientation information output from the geomagnetic sensor.

For reference, the geomagnetic sensor used for calculating the momentum may use a flux gate type magnetic sensor. The geomagnetic sensor decomposes the geomagnetism into the X-axis magnetic field component and the Y-axis magnetic field component and outputs it as an azimuth signal of an analog value, so that the controller 16 counts the change of the magnetic field vector value in the vertical direction to count the user's reward. You can calculate the momentum because you can.

The motion detecting unit 18 may be implemented by employing an acceleration sensor that outputs an acceleration value for a change in movement of the blood sugar managing device 10 itself. In this case, the controller 16 may control the blood sugar managing device from the change of the acceleration value. 10) It is possible to calculate the user's exercise amount by calculating the movement amount of its own up, down, left and right.

The key operation unit 20 includes at least a toggle key and a power on / off key for setting the blood sugar measurement mode and the exercise amount measurement mode.

Referring to the operation of the blood sugar management apparatus having the above-described configuration,

First, the diabetic patient sets the operation mode of the blood sugar managing apparatus 10 to the blood sugar measuring mode, and then contacts the blood with the sensor strip S and inserts the blood into the insertion hole in the blood sugar managing apparatus 10. As such, when the sensor strip S is inserted into the insertion hole, the controller 16 supplies power to the first working electrode S3. As a power supply method, the switches 1 and 2 (SW1 and SW2) shown in FIG. 2 are turned on and the switches 3 and 4 (SW3 and SW4) are kept off.

When blood reaches the reference electrode S1 past the first working electrode S3, current flows between the two electrodes S1 and S3 by the reaction of the enzyme reaction layer. The current flowing through the first working electrode S3 is converted into a voltage by the resistor R1 connected to the output terminal of the operational amplifier OP1 and the inverting terminal (−). The converted voltage is input to the control unit 16 and preferentially converted into digital data. Therefore, the controller 16 can detect the voltage value converted into digital data, that is, the amount of current flowing through the first working electrode S3.

In a similar manner, switches 2 (SW2) and 4 (SW4) are turned on and the switches 1, 3 (SW1, SW3) are turned off to supply power to the second working electrode (S2), so that the second working electrode ( The amount of current flowing in S2) can be detected.

As described above, power is sequentially supplied to the first working electrode S3 and the second working electrode S2 so that the first working electrode S3, the reference electrode S1, the second working electrode S2, and the reference electrode are supplied. When the amount of current flowing through S1 is detected, the controller 16 can read out the blood sugar values corresponding to these average values from the internal memory. If the reference electrode and the working electrode are configured as a sensor strip, the controller 16 simply detects the current flowing through one working electrode and reads the blood sugar value corresponding to the detected current amount from the memory.

As described above, when the blood glucose level measurement is completed, the controller 16 displays this on the display unit 22.

On the other hand, if the user has set the operation mode of the device 10 to the exercise amount measurement mode to measure his or her exercise amount for blood sugar management, the control unit 16 measures the number of vibrations detected by the vibration sensor as an example of the motion detector 18 The exercise amount is calculated by counting and multiplying calories consumed per step. Then, by displaying the calculated exercise amount on the display unit 22, the user will continue the exercise until obtaining the exercise amount necessary for blood sugar management.

According to the embodiment of the present invention as described above, the present invention can obtain the effect of a single benefit that can measure the blood glucose as well as the exercise amount with only one device, the user has a blood sugar management apparatus according to an embodiment of the present invention Through this, you will be provided with the convenience to manage your own blood sugar.

Meanwhile, FIG. 3 is a view for explaining that the blood sugar managing apparatus 10 according to the second embodiment of the present invention is used in combination with the communication terminal 30. FIG. 4 is a blood sugar managing apparatus shown in FIG. The block diagram of the communication terminal 30 connected to the (10) is shown.

Comparing the configuration of the blood sugar managing device 10 shown in FIG. 4 with the blood sugar managing device shown in FIG. 1, except that the display unit 22 shown in FIG. 1 is replaced with the terminal interface unit 22. It is the same as the basic configuration of the blood sugar managing apparatus shown in FIG.

In FIG. 4, the terminal interface 22 serves to interface the blood sugar level or exercise amount obtained by the controller 16 to the portable communication terminal 30. The terminal interface 22 can be combined with the interface connector 31 of the communication terminal 30 as shown in FIG.

On the other hand, the blood sugar managing apparatus 10 shown in FIG. 4 is an advanced form of the blood sugar managing apparatus shown in FIG. 1, and thus it is possible to transmit the measured blood sugar level to the remote place through the communication terminal 30 and the wireless network. It will be useful to receive the information necessary for blood sugar management.

Hereinafter, the portable communication terminal 30 coupled with the blood sugar managing apparatus 10 will be described in detail.

The wireless communication unit 36 modulates and frequency-converts data such as blood sugar level or user exercise amount output from the main body control unit 34 to transmit a wireless signal through the antenna ANT, and receives the wireless signal through the antenna ANT. It separates the blood sugar self-management information from the signal and performs the function of frequency conversion and demodulation and transmitting it to the main body controller 34.

The voice processor 38 digitally processes the voice input through the microphone MIC under the control of the main body controller 34, transmits the voice signal to the wireless communication unit 36, and demodulates the voice data received through the wireless communication unit 36. Output through the speaker (SPK).

The main body controller 34 controls the overall operation of the terminal based on the control program data stored in the internal memory. For example, the blood sugar level or the amount of exercise transmitted from the blood sugar managing apparatus 10 is displayed according to a user command, and the blood sugar level or the amount of exercise is wirelessly transmitted. In addition to demodulating and displaying the blood sugar self-management information transmitted from the designated blood sugar management server, it stores the data according to user selection.

The pack I / F 32 includes a standard interface connector to interface blood sugar values or user exercise data transmitted from the blood sugar managing apparatus 10 to the main body controller 34.

Hereinafter, the operation of transmitting and receiving a signal between the blood sugar managing apparatus 10 having the above-described configuration and the communication terminal 30 will be described. First, the blood sugar level measurement and the exercise amount performed by the blood sugar managing apparatus 10 are the same as those described with reference to FIG. 1. Is measured. For example, the blood sugar value measured by the blood sugar managing apparatus 10 is transmitted to the mobile phone main body 30 through the terminal interface 22.

When the blood sugar level is transmitted from the blood sugar managing apparatus 10, the main body controller 34 displays it on the display unit, which is the user interface unit 40. If the blood sugar level transfer command is input, the main body control unit 34 transmits the displayed blood sugar level to the communication company server 320 together with the blood sugar level transfer code so that the blood sugar level is transmitted to the designated server.

Therefore, the designated server, for example, the blood sugar management server that manages the blood sugar level of the member will be able to provide the blood sugar self-management information necessary for managing the blood sugar level of the member to the member's mail or the company's homepage or communication terminal.

According to the embodiment of the present invention described above, the user self-measures his own blood sugar level through the blood sugar management device 10 and transmits it to a designated server located remotely via the communication terminal 30, the user later manages blood sugar Receive information for your services.

On the other hand, Figure 5 shows a block diagram of the blood sugar management communication terminal 50 according to a third embodiment of the present invention, it can be seen that the configuration for measuring blood glucose and exercise amount inserted in the general communication terminal. Although not shown, an insertion hole into which the blood sugar measurement sensor strip S may be inserted is formed in the main body of the portable communication terminal 50 illustrated in FIG. 5.

In addition, the blood sugar management communication terminal 50 according to the third embodiment of the present invention is a power supply unit 52 for supplying power to the electrode of the blood sugar measuring sensor strip and the current sensing for detecting the amount of current flowing through the electrode The unit 54 further includes a motion detector 56 for detecting motion. The main body controller 58 for controlling the overall operation of the communication terminal reads the blood sugar value corresponding to the amount of current detected by the current sensing unit 54 from the memory and outputs the blood sugar value to the display unit which is the user interface 64 or the motion detection unit. The amount of exercise of the user is calculated from the data output from 56 and output to the display unit. The user can set the operation mode of the terminal 50 in the blood glucose measurement mode and the exercise amount measurement mode through a key operation unit, which is a component of the user interface unit 64.

The blood sugar managing communication terminal 50 shown in FIG. 5 is also a more advanced form than the blood sugar managing apparatus shown in FIG. 1, and since it is possible to transmit the measured blood sugar level to a remote place through a wireless network, it is necessary for blood sugar management. This is useful for getting information.

Since the blood sugar measurement, exercise amount measurement and transmission to the server in the blood sugar management communication terminal 50 are also performed in the same manner as the blood sugar measurement, exercise amount measurement and transmission to the server described in FIG. 4, a detailed description thereof is omitted. Let's do it.

On the other hand, it is possible to build a blood sugar management system using the various types of blood sugar management devices described above. When explaining the blood sugar management system,

First, FIG. 6 is a block diagram of a blood sugar managing system according to an exemplary embodiment of the present invention. More specifically, as shown in FIG. 4, the blood sugar managing apparatus 10 and the communication terminal 30 are combined with each other to manage blood sugar. An example of a system configuration is shown. Alternatively, a blood sugar managing system may be constructed using the blood sugar managing communication terminal 50 illustrated in FIG. 5.

Hereinafter, a blood sugar management system will be described based on the configuration shown in FIG. 6.

First, the portable communication terminal 30, which is a component of the blood sugar management system, displays a blood sugar level or a user's operation amount transmitted from the blood sugar management apparatus 10 through a standard interface connector, and displays the displayed blood sugar level in the designated blood sugar management server ( 90) and wirelessly transmits and receives, displays or stores the blood sugar self-management information transmitted from the server (90).

Since the detailed block configuration of the blood sugar managing apparatus 10 and the portable communication terminal 30 coupled thereto is described in detail with reference to FIG. 4, it will be omitted below.

Meanwhile, the blood sugar management server 90 stores and manages the blood sugar value of the member transmitted from the portable communication terminal 30 as a DB, and recommends exercise data, diet, exercise therapy, and medication management information necessary to control the blood sugar level of the member. It serves to transmit the blood sugar self-management information containing the member to the communication terminal 30 or the mail. The blood sugar management server 90 requests the medical institution server 100 to make a medical appointment for the member when the blood sugar level of the member is a number requiring consultation and medical treatment of the specialist, and the reservation result of the member's communication terminal 30. Can be sent to In addition, the blood glucose level history information, diabetes-related complication information, education information for blood sugar management, diabetes specialized treatment institution information and specialist information can be transmitted to the member information terminal 110 logged in. In addition to the illustrated additional functions, various contents may be provided through wired and wireless networks to meet the needs of diabetes patients and effective diabetes treatment methods.

Since the mobile communication network and the Internet network located between the portable communication terminal 30 and the blood sugar management server 90 are well known, detailed description thereof will be omitted.

Hereinafter, the blood sugar is measured using the blood sugar managing apparatus 10 described above, and the measured blood sugar level is transmitted to the blood sugar managing server 90 through the terminal 30 to be managed, as well as recommended exercise data or blood sugar for the measured blood sugar level. The self-management information will be provided to comprehensively explain the process of blood sugar management by the patient.

First, the diabetic patient sets the operation mode of the blood sugar managing apparatus 10 to the blood sugar measuring mode, and then contacts the blood with the sensor strip S and inserts the blood into the insertion hole in the blood sugar managing apparatus 10. As such, when the sensor strip S is inserted into the insertion hole, the controller 16 supplies power to the first working electrode S3. As a power supply method, the switches 1 and 2 (SW1 and SW2) shown in FIG. 2 are turned on and the switches 3 and 4 (SW3 and SW4) are kept off.

When blood reaches the reference electrode S1 past the first working electrode S3, current flows between the two electrodes S1 and S3 by the reaction of the enzyme reaction layer. The current flowing through the first working electrode S3 is converted into a voltage by the resistor R1 connected to the output terminal of the operational amplifier OP1 and the inverting terminal (−). The converted voltage is input to the control unit 16 and preferentially converted into digital data. Therefore, the controller 16 can detect the voltage value converted into digital data, that is, the amount of current flowing through the first working electrode S3.

In a similar manner, switches 2 (SW2) and 4 (SW4) are turned on and the switches 1, 3 (SW1, SW3) are turned off to supply power to the second working electrode (S2), so that the second working electrode ( The amount of current flowing in S2) can be detected.

As described above, power is sequentially supplied to the first working electrode S3 and the second working electrode S2 so that the first working electrode S3, the reference electrode S1, the second working electrode S2, and the reference electrode are supplied. When the amount of current flowing through S1 is detected, the controller 16 can read out the blood sugar values corresponding to these average values from the internal memory. If the reference electrode and the working electrode are configured as a sensor strip, the controller 16 simply detects the current flowing through one working electrode and reads the blood sugar value corresponding to the detected current amount from the memory.

As described above, when the blood glucose level measurement is completed, the controller 16 transmits the blood sugar level to the mobile phone main body 30 through the terminal interface 22. In this case, the operation mode of the mobile phone main body should be set to the blood glucose measurement mode.

When the blood sugar level is transmitted from the blood sugar managing apparatus 10 in the blood sugar measuring mode, the main body controller 34 displays the same on the display unit, which is the user interface unit 40. If the blood sugar level transfer command is input, the main body controller 34 transmits the displayed blood sugar level to the communication company server 80 together with the blood sugar level transfer code. The communication company server 80 transmits the blood sugar value and the user identification information transmitted together with the blood sugar value transmission code to the contracted blood sugar management server 90. Of course, the information transmitted from the portable communication terminal 30 may simply be directly transmitted to the blood sugar management server 90 through the communication company server 80.

Then, the blood sugar management server 90 separates the members through the received user identification information, and together with the blood sugar value transmitted through the blood glucose value of the member, it is possible to continuously manage the blood sugar level of the member thereafter.

The blood sugar management DB of the blood sugar level DB after the blood sugar self-management information or recommended exercise data including the diet, exercise therapy, medication management information necessary to control the blood sugar level of the member through the communication company server 80 of the member It transmits to the communication terminal 30. The blood sugar self-management information or recommended exercise amount data may be transmitted to a mail account designated by a member.

If the blood sugar level of the member is a number requiring consultation and medical treatment of the specialist, the blood sugar management server 90 requests the medical institution server 100 to make a medical appointment for the member, and the reservation result of the member's communication terminal 30. Can also be sent to.

Meanwhile, the portable communication terminal 30 wirelessly receiving the blood sugar self-management information displays the state and stores the information in the internal memory according to a user command. Since the blood glucose self-management information includes diet, exercise therapy, self-treatment information, and recommended exercise data necessary for controlling the measured blood glucose level, the diabetic patient should follow self-treatment, self-food control, and self-exercise amount according to the information. Adjustment can be performed.

For example, the diabetic patient may check the self-exercise amount according to the exercise therapy guideline transmitted from the blood sugar management server 90 as well as transmit the exercise amount to the blood sugar management server 90. That is, when the diabetic patient walks after setting the blood sugar managing apparatus 10 coupled to the communication terminal 30 to the exercise amount measuring mode, the control unit 16 of the blood sugar managing apparatus 10 moves the movement detecting unit 18. The final amount of exercise (calorimeter consumption) can be calculated by counting the number of steps of the user from the signal output from the. The exercise amount calculated as described above is displayed on the display unit of the communication terminal 30 and is transmitted to the blood sugar management server 90 through the communication company server 80 along with the exercise amount transmission code according to a user command, which can be stored and managed together with the blood sugar value. will be.

Therefore, the diabetic patient can be provided with various benefits that were not enjoyed in the conventional blood glucose meter, for example, by managing the blood glucose level of the diabetic patient, blood glucose self-management information, recommended exercise data, etc., which match the measured blood glucose level. For example, you can enjoy the benefits of using a blood glucose meter as an exercise tracker.

For reference, the diabetic patient logs in to the blood sugar management server 90 through a member information terminal 110 such as a computer, his / her blood sugar level / exercise history information, diabetes related complications information, education information for blood sugar management, diabetes Specialized treatment institution information and specialist information may be provided on the main page or link page.

As described above, the present invention has a single benefit that can calculate and provide the amount of exercise of the diabetic patient affecting blood sugar levels as well as the blood sugar management device itself,

Since the blood sugar management device can be used in combination with a communication terminal, the blood sugar level or exercise amount measured by the blood sugar management device can be transmitted to a remote place for diagnosis by a specialist, as well as recommended exercise data, diet, exercise therapy, and the like. Receiving the same self-management information has the convenience of self-treatment and control of blood sugar levels.

In addition, if a member's blood sugar level requires consultation with a specialist and medical treatment, a request for medical appointment for the member is requested from the medical institution's server, and the reservation result is transmitted to the member's communication terminal. You can go through the procedure, and your own blood sugar level and exercise volume are managed by DB, which can lay the foundation for effective diabetes treatment.                     

On the other hand, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only by the appended claims.

Claims (17)

delete delete delete delete delete delete delete delete In the communication terminal for blood sugar management, the sensor strip insertion hole is formed, A power supply for supplying power to the electrode of the blood sugar measurement sensor strip; A current sensing unit for detecting an amount of current flowing through the electrode; A motion detector for detecting a motion; A terminal main body control unit for reading a blood sugar value corresponding to the detected current amount from a memory and outputting it to a display unit or calculating a user's exercise amount from a signal output from the motion detection unit and outputting it to the display unit; And a key operation unit for setting a blood sugar measurement mode and an exercise amount measurement mode. The method of claim 9, wherein the motion detector is a vibration sensor for detecting the vibration, the control unit for blood sugar management communication terminal, characterized in that for calculating the amount of exercise of the user by counting the number of vibrations detected by the vibration sensor. 10. The method of claim 9, wherein the motion detection unit is a geomagnetic sensor for detecting the geomagnetic and output current orientation information, the control unit calculates the user exercise amount by counting the change in the orientation information output from the geomagnetic sensor Communication terminal. 10. The method of claim 9, wherein the motion detector is an acceleration sensor for outputting an acceleration value for the change in movement, the control unit for blood sugar management communication, characterized in that for calculating the user's exercise amount by moving up, down, left and right from the change in the acceleration value terminal. In the blood glucose measurement mode, a blood glucose value obtained by detecting an amount of current flowing through a sensor strip electrode inserted into a sensor strip insertion hole, and a user's exercise amount are calculated and displayed on a display unit from data obtained through a motion detector in an exercise amount measurement mode. A portable communication terminal for wirelessly transmitting to the server and receiving and displaying recommended exercise data transmitted in response thereto; And a blood sugar managing server configured to store and manage blood sugar values of members transmitted from the portable communication terminal. The method according to claim 13, wherein the blood sugar management server; Glucose management system characterized in that the zoom transmits the recommended exercise data corresponding to the blood glucose level of the member to the communication terminal of the member. The method according to claim 13, wherein the blood sugar management server; Blood sugar management system characterized in that to transmit the blood sugar self-management information, including the diet, exercise therapy, medication management information necessary to control the blood sugar level of the received member to the communication terminal of the member. The method according to claim 13, wherein the blood sugar management server; Blood sugar management system characterized in that the database transmits the member's blood sugar level history information, diabetes-related complications information, education information for blood sugar management, diabetes specialized treatment institution information and specialist information to the logged-in member information terminal. delete

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