KR20090123395A - Sensor strip including code informations and analysis devices using the same - Google Patents

Abstract

PURPOSE: A sensor strip containing coding information and an analyzing apparatus using the same are provided to reduce price without additional accessories. CONSTITUTION: A sensor strip comprises: an insulator substrate(15) on which a test sample is provided; a sensing unit(14) installed at the upper portion of the insulator substrate, which outputs detection signal by reacting with the analysis material; and a coding part(12) installed at the upper portion of insulator substrate, which is arranged according to code value corresponding to the state of the sensing unit. The coding part partitions a code part through laser patterning or by masking conductive material. An analysis device comprises the sensor strip and a device main body in which the sensor strip is inserted and displays the amount of detection of analysate.

Description

Sensor strip including code informations and analysis devices using the same}

The present invention relates to a sensor strip including code information and an analysis device using the same, and more particularly, to provide a code to the sensor strip itself, and does not require a separate additive or additional part for recognizing the code. The present invention relates to a sensor strip including code information that does not require additional action of setting a code to a sensor strip analyzer, and an analysis device using the same.

Sensor strips used for quantitative or qualitative analysis of samples taken from the human body have sensing measurement deviations due to the manufacturing process characteristics of the sensor strips. In order to compensate for the measurement deviation of the produced sensor strip, a unique code that can represent the characteristics of each sensor strip is given.The user recognizes the sensor strip code in the sensor strip analyzer, and then performs the sample analysis. have.

One way to recognize the sensor strip code is to first provide an additional part containing the code along with the sensor strip so that the user can insert the additional part into the sensor strip analyzer to recognize the code. Using a memory chip called 'code chip' is a typical method of storing the sensor strip code in the code chip and providing it with the sensor strip, which can be inserted into or removed from the device. It is easy to use because the user can insert the code chip into the sensor strip analyzer so that the sensor strip analyzer can recognize the code, and even if the characteristics of the strip sensor change, only the code chip needs to be replaced. It has the advantage, but it requires additional code chip cost and it is impossible to measure if the code chip is lost. In addition, if the user inadvertently inserts a code chip with a different code into the sensor strip analyzer, the measurement value of the sample is changed. Therefore, if the medical action is taken according to the measurement result, it may cause a fatal danger to the user.

The second method is to set the code by manipulating the buttons on the sensor strip analyzer. This eliminates the need for a memory chip, which incurs no additional costs beyond the sensor strip, but can result in inaccurate measurements due to the user's omission of code settings and typing errors. There is a drawback that the code may not be available if other sensor strips are made.

In addition, the point of care test (POCT) measuring device has a different sensor strip according to the measurement purpose, and the corresponding analysis device is different. That is, in order to measure blood glucose, cholesterol, liver count, etc., each sensor strip should be measured using the corresponding analysis device. If measurements can be made using the same analytical device, additional manipulation by the user is required for recognition of the sensor strip, and even if the analytical device automatically recognizes the type of each sensor strip, Errors occur in manufacturing processes.

SUMMARY OF THE INVENTION An object of the present invention is to provide a sensor strip including code information that does not require any additional parts or additional parts for recognizing a code and an analysis apparatus using the same.

Another object of the present invention is to provide a sensor strip including code information and an analysis apparatus using the same, which does not require a user to additionally set a code on the sensor strip analyzer.

It is still another object of the present invention to provide a sensor strip including code information for identifying the type of sensor strip and an analysis apparatus using the same.

In order to achieve the above object, the present invention, the insulator substrate is supplied with a sample containing an analyte to be measured; A sensing unit formed on the insulator substrate and outputting a detection signal in response to the analyte; And a coding part spaced apart from the sensing unit and installed on the insulator substrate and arranged according to a code value corresponding to the state of the sensing unit.

The present invention also, the sensor strip; And a device body into which the sensor strip is inserted and receiving a detection signal of the sensing unit to display a detection amount of the analyte, wherein the device body recognizes a code value from the coding part and uses the code value. After correcting the detection signal, and provides a microcontroller for calculating the detection amount of the analyte.

A sensor strip including code information according to the present invention and an analysis apparatus using the same include a code corresponding to a code, for example, a code corresponding to a type of sensor strip for each measurement purpose or a correction function that can compensate for a measurement deviation. This eliminates the need for additional components or additional parts to recognize the code, and eliminates the need for the user to set up the code on the sensor strip analyzer, eliminating measurement errors due to incorrect code settings. It can be prevented and provides user convenience for sensor strip analyzer operation.

The present invention can be widely used in the field of using a sensor for measuring a sample extracted using an in-vitro method such as a blood glucose meter, a cholesterol meter, a GOD / GPT, Glutamate Oxaloacetate Transaminase / Glutamate Pyruvate Transaminase In addition, sensors using electrochemical and optical methods among point-of-care (POCT) measurement methods can add coded parts to the sensor itself by adding coding parts and creating corresponding strip sockets.

In addition, according to the present invention, the same analysis apparatus can be used as a blood glucose measurement sensor, a cholesterol measurement sensor, a liver measurement sensor, or the like without additional user intervention, using the information of the coding part of the sensor strip. (POCT) measuring instruments are available as various measuring sensors.

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

The present invention provides a sensor strip including a code information that does not require any additional parts or actions for recognizing the sensor strip code in the sensor strip analyzer and an analysis apparatus using the same. 1 is a structural diagram of a sensor strip according to the present invention. As shown in FIG. 1, the sensor strip according to the present invention is formed on an insulator substrate 15 to which a sample including an analyte to be measured is supplied, and an upper portion of the insulator substrate 15, and reacts with the analyte. The sensor 14 outputs a detection signal and is spatially separated from the sensor 14 on the insulator substrate 15, and arranged according to a code value corresponding to the state of the sensor 14. Coding part 12 is included.

The state of the sensing unit 14 is a deviation generated during manufacturing of the sensor strip (for example, the concentration of the reactant fixed to the sensing unit 14, the mechanism deviation of the reaction unit 16 and the sample inlet 18). ), Or a type of sensor strip that is different for each measurement purpose such as blood sugar, cholesterol, and liver count. A correction function for correcting the measurement deviation according to the state of the sensing unit 14 and a process according to the sensor strip for each measuring purpose are input to a memory of the measuring device, and the detection function according to the type of the correction function or the sensor strip for each measuring purpose is input. The code number corresponding to the process is entered in the coding part 12.

The coding part 12 may represent a code number as two or more, preferably three to five pad arrangements or connection states, and if the number of pads of the coding part 12 increases, the number of possible pad connection states is possible. That is, the number of code numbers grows exponentially.

The coding part 12 may segment the code part by laser patterning after metal thin film treatment on the insulator substrate 15 or may mask the conductive material by masking a conductive material.

The insulator substrate 15 may be a plastic film, a plastic device, a silicon wafer, or the like, and preferably a plastic film may be used. The sensing unit 14 is formed of an electrode such as a metal thin film, carbon paste, or silver paste, and the reaction unit 16 is formed by fixing reagents such as an enzyme mixture solution and a chemical solution. In addition, in the case of the sensor strip of the electrochemical system, the blood inlet space layer 20 to collect a certain amount of the sample further includes. The sensor strip may be used in addition to the insulator substrate 15 with the upper plate 17 having the sample inlet 18, which is a space for injecting the sample in the case of the optical system, and in the case of the sensor strip of the electrochemical system, A top plate 17 having a vent 19 for facilitating suction of the can be used in addition to the insulator substrate 15.

Next, with reference to FIG. 5, each part of the system structure of the analysis apparatus according to the present invention, ie, the field test (POCT) measuring instrument, will be described. A liquid crystal display (LCD) 1 is a display device for displaying the status and measurement results of a measuring instrument, and a buzzer 2 is a sound device for notifying a status sound, a warning sound, etc. of the measuring instrument, and a temperature sensor. (3) is an apparatus for measuring the temperature of a measurement environment. Micro controller unit (MCU) (4) is a device for controlling the entire system of the instrument and measurement algorithms and calculations, Button (5) is an input device for checking the operation of the user, Source (Source) Reference numeral 6 denotes a voltage source or a light source applied to the sensor portion of the strip. Detection 7 is a signal receiver from the strip's sensor, and Electrode Switch 8 is an electrochemical system, where the sensor electrode is the source 6 and the detection of the system. Detection and switch for connection (7). Coding Devider (9) is a device that automatically sends a signal for the code number of the sensor strip 11 to the microcontroller 4 when the sensor strip 11 is inserted into the strip socket 10, The strip socket 10 is a connector to which the sensor strip is connected to the meter. The sensor strip 11 is a sensor that outputs an electrical or optical signal when a measurement sample is applied. ).

More specifically, the microcontroller 4 recognizes a code value from the coding part 12, and corrects the sensing unit detection signal of the sensor strip 11 using the code value, and then detects the detected amount of the analyte. To calculate.

The strip socket 10 has a pin for electrical connection with the coding part 12 and a strip check pin for checking whether the sensor strip 11 is inserted. The pin for electrical connection with the coding part 12 checks the state of the coding part 12 of the sensor strip 11 through contact with the pads of the coding part 12 of the sensor strip 11 to determine the state of each. Make it possible to recognize the unique code number corresponding to The number of the pins is two or more, preferably three to five, depending on the number of pads of the coding part 12.

In addition, in the case of the electrochemical system, the strip socket 10 further includes an electrode pin for electrical connection with a sensor to which a sample of the sensor strip 11 is applied.

The coding divider is a device that transmits a signal for a code number to the microcontroller 4 as a voltage value by dividing the positive voltage V + by different resistance distributions according to the pad arrangement state of the coding part 12.

Hereinafter, preferred examples for aiding in understanding the present invention are presented. The following examples are intended to illustrate the invention and are not intended to limit the invention.

[Example] Code Numbering Method in Case of Three Pins for Electrical Connection with Coding Part of Strip Socket

 As shown in FIG. 3, in the case of an electrochemical or optical analysis system, when necessary by laser patterning after metal thin film treatment on the sensor strip plastic film, the cord portion is disconnected between ①, ②, ③ The cord portion was partitioned by masking or masking the conductive material on the sensor strip plastic film. Table 1 is given a code number according to the connection state of the pad (①, ②, ③) of the sensor strip coding part.

Code number Coding Part Pad Connection Status Reference CODE 1 ①, ②, ③ all cut

CODE 2 Connect only ① and ②

CODE 3 Connect only ② and ③

CODE 4 ①, ②, ③ all connected

CODE 5 Connect only ① and ③

Referring to Figure 4, a method of automatically recognizing the code number to the meter using the sensor strip will be described. When it is confirmed that the sensor strip 11 is inserted into the strip socket 10 through the strip check pin, the pins ① ′, ② ′, ③ ′ of the strip socket 10 are replaced with the pads ① of the sensor strip 11. , ②, ③ check the connection status. That is, the state of the coding part 12 of the sensor strip 11 is checked through contact with ① to ① ', ② to ②', and ③ to ③ 'and recognized as a unique code number corresponding to each state.

When inserting a sensor strip having a different state of the coding part 12 according to each code number into the strip socket 10 of the measuring device, the microcontroller 4 of the meter automatically recognizes the code number. Coding divider 9 is located between and microcontroller 4.

The coding divider 9 divides the positive voltage V + into different distributions of resistance according to the pads (①, ②, ③) of the coding part 12 of the sensor strip 11. The resistor divided voltage value is input to an analog to digital converter (ADC) pin of the microcontroller 4 to recognize a code number corresponding to the level of each voltage value.

Code number Coding Part Pad Connection Coding Dividers CODE 1 ①, ②, ③ all cut

CODE 2 Connect only ① and ②

CODE 3 Connect only ② and ③

CODE 4 ①, ②, ③ all connected

CODE 5 Connect only ① and ③

Table 2 shows voltage division states of coding dividers according to code numbers. As shown in Table 2, the voltage value input to the ADC pin of the microcontroller 4 is independent of each code number. Thus, the microcontroller 4 automatically recognizes the code number according to the voltage level from the coding divider 9.

The code number thus recognized can be used, for example, as follows. First, in the measurement of blood sugar, cholesterol, liver count, etc., in order to reduce the deviation of the sensor strip, it can be used as a code for correcting the sensor strip deviation. Second, for the same analysis device, the type of sensor strip is automatically recognized according to the code number of the sensor strip so that various types of sensor strips can be used. For example, the analysis device recognizes that the sensor strip for blood sugar measurement is recognized as CODE 1 from the coding part of the sensor strip, the sensor strip for cholesterol measurement if it is recognized as CODE 2, and the sensor strip for measurement of liver counts if it is recognized as CODE 3, The measuring process can then be executed.

1 is a structural diagram (electrochemical method, optical method) of the sensor strip of the present invention.

Figure 2 is a side view (electrochemical, optical) of the sensor strip and strip socket of the present invention.

3 is a structural diagram of the sensor strip and strip socket of the present invention (electrochemical method, optical method).

4 is a schematic diagram of coding divider structure for automatic code recognition of a sensor strip of the present invention (in case of CODE 1).

5 is a system structural diagram of an analysis device of the present invention.

Claims (8)

An insulator substrate supplied with a specimen including an analyte to be measured; A sensing unit formed on the insulator substrate and outputting a detection signal in response to the analyte; And And a coding part spaced apart from the sensing unit and installed on the insulator substrate and arranged according to a code value corresponding to the state of the sensing unit. The sensor strip of claim 1, wherein the coding part partitions the code part by laser patterning after metal thin film treatment on the insulator substrate, or partitions the code part by masking a conductive material. The sensor strip of claim 1, wherein the coding part comprises two or more conductive pads, and contact states of the two or more conductive pads are different from each other according to a state of the sensing unit. The sensor strip of claim 1, wherein a code value corresponding to a state of the sensing unit is a code value corresponding to a type of a sensor strip or a deviation generated during manufacturing of the sensor strip. An insulator substrate supplied with a specimen including an analyte to be measured; A sensing unit formed on the insulator substrate and outputting a detection signal in response to the analyte; And a sensor strip that is spatially separated from the sensing unit and is provided on the insulator substrate, and includes a coding part arranged according to a code value corresponding to a state of the sensing unit. And The sensor strip is inserted, and receives a detection signal of the sensing unit and includes a main body of the device to display a detection amount of the analyte, And the device main body includes a microcontroller that recognizes a code value from the coding part, corrects the detection signal using the code value, and then calculates a detection amount of the analyte. The device of claim 5, wherein the device body comprises a strip socket having two or more pins for electrical connection with the coding part and a strip check pin for checking the insertion of the sensor strip. The analysis device according to claim 5, wherein the device main body includes a coding divider for dividing a positive voltage (V +) by different resistance distributions according to a pad arrangement state of the coding part. The analysis apparatus of claim 5, wherein a code value corresponding to a state of the sensing unit is a code value corresponding to a type of a sensor strip or a deviation generated during manufacturing of the sensor strip.

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