KR20100006400A - Calibration method for bio-sensor - Google Patents

Abstract

PURPOSE: A method for correcting a biosensor is provided to enhance convenience of use by omitting recognition process of correction code and reduce production price. CONSTITUTION: A method for correcting a biosensor comprises: a step of calculating correction value to obtain a code based on the correction value; a step of classifying and correcting biosensors having same code and receiving in one sensor container; a step of inputting correction value information to a measuring device; and a step of correcting measured result using correction value information.

Description

Calibration method for bio-sensor

The present invention relates to a calibration method of a biosensor, and more particularly, to a method for correcting an error of a sensor itself generated in a manufacturing process of a biosensor.

A biosensor is a system that converts information into a useful signal that can be recognized, such as color, fluorescence, and electrical signals, by using biological elements or mimicking biological elements when obtaining information from a measurement object.

In particular, biosensors using biological enzymes have excellent sensitivity and specificity of reaction, and thus they are expected to be applied in a wide range of fields, such as the medical / medical field, the process measurement of the bio industry, the environmental measurement, and the stability evaluation of chemicals.

Investigating chemical components in vivo is very important medically, and biomedical sensors are widely used to analyze biological samples such as blood in the medical diagnostic field.

Among them, enzyme assay biosensors using specific reactions of enzymes and substrates or enzymes and inhibitors are most widely used in hospital and clinical chemistry analysis because they are easy to apply and use, have excellent measurement sensitivity, and have fast results. .

Enzyme assays for examining chemical components in vivo can be classified into colorimetric methods for observing light transmittance before and after enzymatic reaction by spectroscopic methods and electrode methods for measuring electrochemical signals.

Among these methods, the color development method requires a longer measurement time, requires a large amount of blood, and is difficult to analyze important biomaterials due to measurement errors due to turbidity of biological samples.

Therefore, in recent years, an electrode system composed of a plurality of electrodes is formed on a plastic film (insulating substrate) by etching, screen printing, sputtering, etc. Electrode method for quantitatively measuring substances has been applied to many biosensors using enzymes.

In the case of using the electrode method, a separate measuring device for reading information about the biomaterial from the biosensor is required, and the measuring device includes a socket electrically connected to the thin film electrode of the biosensor. When the thin-film electrode of the biosensor is inserted into the measuring instrument through the insertion hole, the thin-film electrode is connected to the terminal formed in the socket of the measuring instrument. Then, the measuring instrument receives information about the biomaterial to be analyzed while the measuring instrument is turned on. do.

One of the widely applied biosensors of the electrode method is a blood glucose meter, and anyone can easily collect his own blood and measure the amount of glucose (blood sugar) in the blood.

In insulin-dependent patients who need to measure blood glucose in real time two or three times a day, the fingertip is usually pierced with a needle-shaped lancet, and the blood glucose meter is used to collect the sample (blood) and the reactants in the biosensor. The blood glucose value is measured from the electrical signal generated by the electrochemical reaction.

In other words, the enzyme reaction layer composed of hydrophilic polymer, oxidoreductase, and electron acceptor is fixed on the electrode system of the biosensor, and the user injects a sample (blood) containing a substrate (glucose) through the sample inlet of the biosensor. By contacting the enzyme reaction layer, the enzyme reaction layer dissolves it, the substrate of the sample and the enzyme (Enzyme) is reacted, and the substrate is oxidized and the electron acceptor is reduced. The oxidation current obtained by electrochemically oxidizing the reduced electron acceptor can be measured through a measuring instrument to determine the concentration of the substrate contained in the sample.

Meanwhile, in the manufacturing process of the biosensor, the sensor checks whether the blood glucose measurement is accurate or the error range for each sensor, and inputs correction value according to the error of the sensor itself to each sensor at the time of manufacturing, and the sensor is used when the sensor is used. After confirming the error information from the error correction is used to display the final result value.

For example, after the code containing the correction value is formed in the biosensor, the measuring device checks the correction value from the code of the sensor in use and displays the measurement result value reflecting the correction value. That is, when the blood glucose reference value is 100, if the measured value of the first sensor is 100, the code A is given. If the measured value of the second sensor is 90, the code B is added to add 10 (correction value) to make 100. If the measured value of the third sensor is 110, code C is given to subtract 10 to make 100.

As a method of providing a code containing correction information for each sensor as described above, a method of determining the shape of an electrode corresponding to each code and then forming an electrode corresponding to the code on the substrate of the sensor is used. At this time, the shape of the electrode is determined differently according to the code and the correction value.

Therefore, when the sensor is inserted into the socket connected to the measuring device, the plurality of terminals installed inside the socket recognizes the electrodes of different shapes for each code, thereby correcting the measured value with a correction value corresponding to each code in the blood glucose measurement apparatus.

As described above, a code recognition electrode for providing a correction value code is formed on one side of a substrate of a biosensor, and a measuring instrument identifies the electrode for code recognition, and the code and correction value applied to the sensor are used for the code recognition. Through the electrodes, the measuring device recognizes the correction value in the measurement result.

However, the method of forming the code recognition electrode has a problem in that a separate electrode must be formed in order to give a code to the sensor after setting the code according to the correction value in the manufacturing process.

This not only complicates the manufacturing process of the biosensor, but also causes various problems such as an increase in the number of processes, an increase in manufacturing manpower, and an increase in manufacturing time, and there is a disadvantage of increasing the manufacturing cost of the biosensor due to the use of electrode materials.

Of course, a method of displaying a specific code in a form that can be visually identified by the user may be used instead of an electrode for code recognition, but this is inconvenient for the user to identify the code assigned to each sensor and input it to the measuring instrument each time the sensor is used. have.

In addition, even if the measuring device is equipped with a specific means for reading the code display of each sensor, there is an inconvenience to read the code display for every sensor every time you use.

Accordingly, the present invention has been invented to solve the above problems, the user inputs a correction value code assigned to each sensor for each use of the biosensor as in the prior art, or the measuring instrument is input from the electrode for code recognition of the biosensor. It is an object of the present invention to provide a method of correcting a biosensor, in which a process of recognizing a correction value code is unnecessary, and a manufacturing process is simpler and a process number can be reduced and manufacturing cost can be reduced, compared to forming a code recognition electrode for each sensor.

In order to achieve the above object, the present invention comprises the steps of obtaining a correction value for correcting the error of the sensor itself for each biosensor in the manufacturing process of the biosensor and giving a code according to the correction value; Collect and collect biosensors with the same code and store them in the same sensor container, and form codes recognizable in the form of recognizable codes in the sensor containers housed by the biosensors of the same code. Providing; Inputting correction value information into a measuring device by a user reading a code of a sensor container using a code recognition means; When the measurement is initiated by inserting the biosensor into the measuring device, the measuring device corrects the measurement result using the correction value information obtained from the code of the sensor container.

In a preferred embodiment, the code formed in the sensor container is a bar code containing the correction value information, the code recognition means of the measuring device is characterized in that the bar code scanner.

Further, the correction value information obtained from the code input by the code recognition means is continuously used to correct the sensor measurement result until a new code is input by the measuring instrument. When the new code is input by the code recognition means, the correction value information is updated. The updated correction value information is used for correction of the sensor measurement result.

Accordingly, according to the calibration method of the biosensor according to the present invention, after the sensors having the same correction value codes are stored in each sensor container, the correction value codes of the stored sensors are formed in the sensor container in the form of a code for recognizing the device. And, before using the biosensor, the correction value code of the corresponding sensor container is input to the measuring device using the code recognition means, and when the measurement is started, the measuring device corrects the measurement result using the correction value information obtained from the correction value code of the sensor container. By doing so, there are the following advantages.

1) As before, a user inputs a correction value code assigned to each sensor for each use of the biosensor, or a process in which the measurement unit recognizes the correction value code from the electrode for code recognition of the biosensor is unnecessary and becomes simple to use.

2) Compared to forming an electrode for code recognition for each sensor, the manufacturing process is simpler, and the number of processes can be reduced and manufacturing cost can be reduced.

Hereinafter, the features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. The terms or words used in the present specification and claims are consistent with the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It should be interpreted as meaning and concept.

1 is a view showing a measuring device having a sensor container and a scanner with a barcode attached to the present invention, Figure 2 is a schematic diagram showing an example of a barcode displayed on the sensor container in the present invention, Figure 3 According to the biosensor calibration method.

The present invention relates to a method of calibrating a biosensor. The main feature of the present invention is to improve a method of inputting correction value information of a biosensor to a measuring device so that the measuring device 10 can correct an error of the sensor itself when the biosensor 23 is used. There is this.

As described above, in the manufacturing process of the biosensor, each sensor checks whether the measured value is accurate or the extent of the error range, and codes according to the correction value for each sensor so that the sensor itself can correct the error in manufacturing. (E.g., an electrode for code recognition) is provided. That is, when the correction value is determined using the measured value of the sensor in the manufacturing process, it is classified into codes A, B, C, etc. according to the obtained correction value, and the corresponding code is provided for each sensor. Accordingly, the measurement unit recognizes the code given to the sensor and reflects the correction value corresponding to the code in the measurement result to display the final result value. However, the provision of a code according to the correction value for each sensor as described above causes a variety of problems when the sensor is manufactured or when the sensor is used.

Therefore, in the present invention, if a code according to the correction value is given to each sensor 23 in the manufacturing process (S1), after classifying and collecting the sensors given the same code (S2), one same sensor container 21a to 21d. (S3), codes 22a to 22d corresponding to the correction values of the sensors stored therein are formed in each sensor container in which the sensors of the same code are stored in the form of a code capable of device recognition (S4).

As described above, in the present invention, by storing the sensors having the same correction value code in one sensor container, and providing the correction value codes of the stored sensors in the form of codes that can be recognized by the device in the sensor container, the correction value codes are individually provided in units of sensors. Rather, the sensor container is used as an information provision and code recognition unit to provide correction value information of the sensors stored therein.

In a preferred embodiment, the correction value codes 22a to 22d capable of device recognition provided to the sensor containers 21a to 21d may be barcodes attached to the outside of the container. In this case, the bar code containing the correction value information may be provided with a bar code indicating various product information on the sensors housed in the containers (21a ~ 21d) (see Fig. 2). For example, a bar code containing correction value information is provided on the side end along with product information such as manufacturing date and effective date of sensors stored in a container. Of course, in this case, the sensors housed in one of the sensor containers 21a to 21d should be sensors having the same product information as the manufacturing date and the effective date as well as the correction value information.

In order to provide the correction value information of the sensor as described above, in the present invention, barcodes are determined for each correction value information (correction value code), and the barcodes 22a to 22d containing the correction value information of the sensor are stored in the containers 21a to 21d in which the sensor is stored. The bar code is determined differently according to the correction value information.

The content of the bar code is input to the measuring device 10 using a code recognition means that can recognize the bar code information, that is, a barcode scanner 13, the scanner 13 is connected to the measuring device 10 by a cable or measuring device Directly coupled to the form, or may be integrally attached to the outside of the meter or embedded in the meter integrally.

The correction value code input by the scanner 13 is transferred to a calculating means for calculating and outputting a measurement result from the signal of the biosensor 23 in the measuring device 10 and used to calculate a final result value. The final result is calculated by reflecting the preset correction value according to the barcode in the measurement result.

That is, the contents of the barcodes 22a to 22d attached to the respective sensor containers 21a to 21d, that is, the correction value information of the stored sensors, are input to the measuring device 10 using the scanner 13, and then the user enters the sensor container. After taking out the biosensor 23 and inserting it into the measuring instrument 10, the blood is introduced into the sample inlet 24 of the sensor to start the measurement, and the measuring instrument 10 measures the correction value obtained from the barcode. After correcting the reflection, the final result value is displayed on the display 12.

In the present invention, the calculation means of the measuring device 10 is to correct the measurement result obtained from the biosensor 23 by continuously inputting the correction value information previously inputted before the new bar code content containing the correction value information is input through the scanner 13. It is provided for use. In addition, when a new bar code content containing correction value information is input through the scanner 13, the correction value information is updated to use the new correction value information for correction of the measurement result.

Accordingly, when the user continues to use the biosensors stored in one sensor container 21a to 21d, the measuring device 10 continuously uses the correction value information read from the barcodes 22a to 22d of the sensor container. As a result of the calibration, the user does not need to read the barcode of the sensor container for the biosensor taken out of the same sensor container.

As a result, the user does not need to input a calibration value code assigned to each sensor every time the user uses the biosensor, or the measuring unit recognizes the calibration value code from the biosensor code recognition electrode. Assuming a continuous use of the sensors of ~ 21d), simply input the barcodes 22a to 22d of the sensor container once, so that accurate results in which manufacturing errors are corrected for several sensor measurements can be measured later. However, the barcode of the changed container may be input only when the sensor stored in the other container is newly used, and an additional barcode input is unnecessary when the sensor of the changed container is continuously used thereafter.

Of course, a method of directly inputting correction value information using a scanner from a bar code of a sensor by forming a bar code on each sensor is applicable. In this case, there is inconvenience in that a user reads a bar code using a scanner every time the sensor is used. On the other hand, in the present invention, if the user uses only the sensor container, the sensor automatically corrects the measurement result without additional use of the scanner and displays the correct measurement result for the sensors taken out of the same container.

In the above, a specific preferred embodiment according to the present invention has been described. However, it is to be understood that the present invention is not limited to the above-described embodiments, and the above-described embodiments merely represent a part of various embodiments to which the principles of the present invention are applied. Those skilled in the art to which the present invention pertains will be capable of various modifications without departing from the spirit of the technical idea of the present invention described in the claims below.

1 is a view showing a measuring device having a sensor container and a scanner with a barcode attached to the present invention,

Figure 2 is a schematic diagram showing an example of a bar code displayed on the sensor container in the present invention,

Figure 3 is a flow chart showing a calibration method of the biosensor according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: measuring instrument 11: insertion hole

12 display 13 barcode scanner

21a: sensor container 22a: barcode

23: biosensor 24: sample inlet

Claims (3)

Obtaining a correction value for correcting an error of the sensor itself for each biosensor in the manufacturing process of the biosensor and giving a code according to the correction value; Collect and collect biosensors with the same code and store them in the same sensor container, and form codes recognizable in the form of recognizable codes in the sensor containers housed by the biosensors of the same code. Providing; Inputting correction value information into a measuring device by a user reading a code of a sensor container using a code recognition means; Correcting the measurement result by using the correction value information obtained from the code of the sensor container when the biosensor is inserted into the measuring device and the measurement is started; Correction method of a biosensor comprising a. The method according to claim 1, The code formed in the sensor container is a barcode containing correction value information, and the code recognition means of the measuring device is a biosensor calibration method, characterized in that the barcode scanner. The method according to claim 1, The correction value information obtained from the code input by the code recognition means is continuously used to correct the sensor measurement result until a new code is input at the measuring instrument, The correction value information is updated when a new code is input by the code recognition means, and the updated correction value information is used to correct the sensor measurement result.

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