KR20060024131A - Blood sugar detection system - Google Patents

Abstract

Configure the blood sugar measuring device as an independent module, connect it to the serial interface of the mobile phone and instruct the measured blood sugar information through the display provided in the mobile phone, and transmit the measured blood sugar information to the blood sugar management service provider and the doctor in real time. It provides instant blood sugar management and treatment services, provides information on blood glucose readings periodically, and alerts you to sudden changes in blood sugar to prevent accidents.

In addition, by sharing the blood sugar information with the doctor in charge is provided a stable care and management services from a remote location.

Blood glucose measurement, mobile terminal, diabetes, remote site management, real time management

Description

Blood sugar measuring device {Blood Sugar Detection System}

1 is a block diagram of a blood glucose measurement apparatus according to the present invention.

2 is a diagram illustrating a connection between a blood sugar measuring apparatus and a mobile phone according to the present invention.

3 is a view illustrating a state in which blood sugar measurement is performed by connecting a blood sugar measuring apparatus and a mobile phone according to the present invention.

The present invention relates to a blood glucose measurement apparatus, and more particularly, to configure the blood sugar measurement apparatus as an independent module, and to access the serial interface of the mobile phone to indicate the blood sugar level information measured through a display provided in the mobile phone, and the measured blood sugar level The present invention relates to a blood glucose measurement apparatus that transmits information to a blood sugar management service provider in real time to receive immediate blood sugar management and treatment services.

Diabetes is a chronic disease that occurs frequently in modern people, and in Korea, more than 2 million people, or 5% of the total population.

Diabetes is an absolute deficiency or relative lack of insulin produced by the pancreas due to a variety of causes, including obesity, stress, poor eating habits, and congenital heredity. It is caused by becoming many.

Blood usually contains a certain concentration of glucose, and tissue cells are getting energy from it.

However, when glucose is increased more than necessary, it is not properly stored in the liver, muscle, or fat cells, and accumulates in the blood, which causes diabetes patients to maintain a much higher blood sugar level than a normal person, and excessive blood sugar passes through the tissues directly into the urine. As it is released, the sugar that is absolutely necessary for each tissue of the body is insufficient, causing abnormalities in each tissue of the body.

Diabetes is characterized by almost no symptoms in the early stages, and when the disease progresses, it is characteristic of diabetes mellitus, polyposis, polyuria, weight loss, general boredom, itching of the skin, and long-lasting wounds on the hands and feet. When the disease progresses further, complications develop into vision disorders, hypertension, kidney disease, stroke, periodontal disease, muscle spasms and neuralgia, gangrene, and the like.

In order to diagnose this diabetes and manage it to prevent progression to complications, systematic blood glucose measurement and treatment should be combined.

For diabetics and people who have not advanced to diabetes but have detected more than normal sugar in their blood, many medical device manufacturers provide various types of portable glucose measuring devices to measure blood glucose at home.

However, such a portable blood glucose measurement device can only check the information of the sugar contained in the blood of the user or the subject, and even in an emergency situation because the user cannot know whether the information of the confirmed sugar is dangerous or the degree to which prompt action is required. There is a disadvantage that you cannot take prompt action.

In addition, there is a disadvantage that does not provide information on what emergency measures to take, even in situations where a large amount of sugar is measured, requiring prompt action.

The present invention has been invented to solve the above problems, the object is to configure the blood glucose measurement device as an independent module, and to access the serial interface of the mobile phone to indicate the information measured through the display provided in the mobile phone, The measured blood sugar level information is transmitted to the blood sugar management service provider in real time so that they can receive immediate blood sugar management and treatment services.

The present invention for realizing the above object is a strip connection to which the test strip is connected; A blood glucose measurement unit including an active electrode including glucose oxidase and an inactive electrode not containing glucose oxidase at a reaction site of the test strip; An ADC for converting the glucose oxidation current in an analog state measured by the blood sugar measuring unit into a digital signal; A microprocessor for measuring blood glucose from the magnitude of the glucose oxidation current generated by the reaction between the active electrode and the inactive electrode by analyzing a signal of the glucose oxidation current applied through the ADC through a set algorithm; A communication unit connected to a mobile communication terminal to transmit and receive data through a serial interface; The present invention provides a blood glucose measurement apparatus including a DAC for converting a digital control signal applied from a microcontroller into an analog signal and transmitting the same to a blood sugar measurement unit.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the blood glucose measurement apparatus according to the present invention includes a strip connection unit 210, a blood sugar measurement unit 220, an ADC 230, a microcontroller 240, a communication unit 250, and a DAC 260. It comprises a separate module, and is connected to the UART contactor of the mobile communication terminal 100 to perform data transmission and reception via the serial interface.

Power for the independent module is operated by being supplied from the mobile communication terminal 100 to be connected.

The strip connection part 210 sucks the blood sample dropped on the drop port and connects a test strip having an elongated shape.

The blood glucose measurement unit 220 includes an active electrode including glucose oxidase and an inactive electrode not containing glucose oxidase at a reaction site of the strip.

The ADC 230 converts the glucose oxidation current in the analog state measured by the blood sugar measuring unit 220 into a digital signal and applies it to the microprocessor 240.

The microprocessor 240 analyzes the signal of glucose oxidation current applied through the ADC 230 through the set algorithm to determine the concentration of sugar in the blood from the magnitude of the glucose oxidation current generated by the reaction between the active electrode and the inactive electrode. Measure

In addition, the measured blood sugar information is transmitted to the connected mobile communication terminal 100 to be displayed on the display, and a correction value for the test strip is set according to a signal applied from the mobile communication terminal 100.

The communication unit 250 executes transmission and reception of data through a serial interface such as RS-232C communication with the connected mobile communication terminal 100.

The DAC 260 converts a control signal applied from the microcontroller 240 to an analog signal by using a digital analog converter and transmits the analog signal to the blood sugar measurement unit 220.

Operation of the blood glucose measurement apparatus according to the present invention consisting of a configuration including the function as described above is as follows.

First, as shown in FIG. 2, when the blood glucose measurement apparatus 200 configured as an independent module is connected to a UART connector formed at the bottom of the mobile communication terminal 100, the blood glucose measurement apparatus 200 is connected to the mobile communication device. Power is supplied from the terminal 100 to activate the blood sugar program to enter the blood sugar measurement mode.

In this case, each test strip has a different glucose oxidase value, and when the correction value indicated on the outer case of the test strip is set by the key input of the mobile communication terminal 100, the microprocessor 240 sets the correction. Set the value.

Thereafter, as shown in FIG. 3, when the test strip is connected to the strip connecting portion 210 and then a certain amount of blood sample is collected using a blood collector installed at the tip of the test strip, the collected blood sample is transferred to the strip. It flows through the formed line to the reaction site where the oxidase is located.

At this time, the glucose contained in the blood sample is reduced by the transfer of electrons to the flavin adenine dinucleotide (FAD) of the enzyme by the oxidation potential applied to the active and inactive electrodes in the blood glucose measurement unit 220 (FADH ₂ ) Itself is oxidized to gluconic acid.

The reduced FADH ₂ oxidizes through the medium, generating a current proportional to the glucose concentration in the blood sample.

As described above, the analog signal for the current having a magnitude proportional to the glucose concentration contained in the blood sample is converted into a digital signal through the ADC 230 and applied to the microcontroller 240.

Accordingly, the microcontroller 240 analyzes the signal of the glucose oxidation current applied through the ADC 230 and takes into account the correction value set for the test strip in the magnitude of the glucose oxidation current generated by the reaction between the active electrode and the inactive electrode. The concentration of sugar in the blood is measured.

The blood sugar information measured as described above is transmitted to the mobile communication terminal 100 through the communication unit 250 through the serial interface, and displayed on the display in a manner that can be easily recognized by numbers or letters.

At the same time, the mobile communication terminal 100 transmits the measured blood glucose information data by accessing a blood sugar management service provider, a doctor in charge, or a web server operated by the user.

Therefore, a remote blood sugar management service provider or a doctor in charge provides dietary information, exercise information, and medication information for managing blood sugar levels according to the received blood sugar information.

In addition, the web server provides a description and guide information about the blood glucose measurement apparatus 200 connected to the mobile communication terminal 100 to the user through an SMS text service.

In addition, by providing information about the blood glucose measurement data to the family periodically or to inform the rapid changes, to ensure rapid blood sugar management to prevent accidents in advance.

In addition, real-time information sharing with the attending physician provides efficiency in treatment.

In the above, when the measured blood glucose information data is not transmitted to the web server or the blood sugar management service provider, the mobile communication terminal 100 repeatedly transmits the measured information at a set interval so that reliable transmission of the measured information is provided.

 As described above, the present invention provides a blood glucose measurement apparatus connected to a mobile communication terminal, so that a user who needs blood sugar management transmits the measured blood glucose information to a blood sugar management service provider or a doctor in real time for rapid blood sugar management. to provide.

In addition, the real-time blood sugar information sharing with the doctor in charge provides efficiency in treatment, is produced in a module form is easy to carry, and provides convenience and efficiency to use by accessing the mobile communication terminal as needed.

Claims (7)

A strip connection to which the test strip is connected; A blood glucose measurement unit including an active electrode including glucose oxidase and an inactive electrode not containing glucose oxidase at a reaction site of the test strip; An ADC for converting the glucose oxidation current in an analog state measured by the blood sugar measuring unit into a digital signal; A microprocessor for measuring blood glucose from the magnitude of the glucose oxidation current generated by the reaction between the active electrode and the inactive electrode by analyzing a signal of the glucose oxidation current applied through the ADC through a set algorithm; A communication unit connected to a mobile communication terminal to transmit and receive data through a serial interface; And a DAC which converts the digital control signal applied from the microcontroller into an analog signal and transmits the digital control signal to the blood glucose measurement unit. The method of claim 1, And the microprocessor transmits the measured blood sugar information to a connected mobile communication terminal and displays it on a display. The method of claim 1, And the microprocessor sets a correction value for the test strip according to a signal applied from a mobile communication terminal. The method of claim 1, The blood sugar measuring device is composed of an independent module, the blood sugar measuring device, characterized in that using the power of the mobile communication terminal. The method of claim 1, The mobile communication terminal to which the blood sugar measuring device is connected transmits the measured blood sugar information to a set blood sugar management service provider, a doctor's mobile communication terminal, or a management web server in real time, and provides blood sugar management information from a blood sugar management service provider and a doctor in real time. Blood sugar measuring device, characterized in that provided by. The method of claim 1, The mobile communication terminal to which the blood sugar measuring device is connected performs retransmission at a set time interval when the real time transmission of the measured blood glucose information fails. The method of claim 1, The mobile communication terminal to which the blood sugar measuring device is connected is provided with blood sugar level management information by SMS text service, voice message, real voice of an administrator or a doctor in charge.

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