KR102539709B1 - Electrochemical measuring device for providing interface for performing biological diagnosis - Google Patents

Abstract

A potentiostatic electrochemical measurement device for biodiagnosis, comprising: multi-channel sensors; control unit; and a display, wherein the control unit, in a state where a first user interface (UI) is displayed on the display, when an input to a region for measurement setting included in the first UI is recognized, sets a plurality of measurement channels. Controls the display to display a second UI for setting measurement items for each measurement channel, wherein the second UI includes a measurement sequence setting area, a measurement type setting area, and a measurement parameter setting area. 2 Control the display to display a UI; Control of setting measurement items for each measurement channel for the plurality of measurement channels is performed using the second UI, and one or more measurements are performed for the plurality of measurement channels through the measurement sequence setting area. Set the measurement sequences consisting of for each measurement channel, set the measurement type corresponding to each of the one or more measurements for each measurement channel through the measurement type setting area, and set the one or more measurements through the measurement parameter setting area. Disclosed is a potentiostatic electrochemical measurement device configured to perform control of setting measurement parameters according to the measurement type for each measurement channel for each of the measurement channels and setting measurement items for each measurement channel for each of the plurality of measurement channels. .

Description

A potentiostatic electrochemical measuring device that provides an interface for performing biodiagnosis

The present invention relates to a method for performing biodiagnosis through a potentiostatic electrochemical measurement device and a potentiostatic electrochemical measurement device for biodiagnosis. More specifically, the present invention provides a method for performing potentiostatic electrochemical measurement for each channel through multi-channel sensors of a potentiostatic electrochemical measurement device for biodiagnosis, and a measurement sequence and measurement type for each channel to perform the method. It relates to a potentiostatic electrochemical measuring device that provides a user interface (UI) for setting.

A potentiostat is a type of electrochemical analysis for the analyte. A specific input voltage is applied to the electrolyte, and the output current generated therefrom is observed to determine which substances are present in the electrolyte to be analyzed according to the characteristics of the output current. It can mean a method of detection.

A device that analyzes a target substance in a potentiostat method, that is, a potentiostatic electrochemical measuring device may be used for biodiagnosis. When potentostat detection is performed on a specimen to be diagnosed collected from the human body, whether or not the substance to be detected is present in the specimen can be confirmed, and various biodiagnostics can be performed therefrom.

However, when a potentiostatic electrochemical measuring device is used for biodiagnosis, various types of potentiostat measurements may be required for the same sample, which can take a lot of time for sample analysis in large hospitals or laboratories. In addition, if the process of separately digitizing or visualizing the output current obtained as an analysis result is performed in an analysis equipment other than a measurement device, the procedure of measuring a potentiometer for biodiagnosis may become complicated.

As described above, it is required to improve the performance of the potentostat device in order to solve the problems caused by excessive analysis time and complicated analysis procedures that occur when biodiagnosis is performed using the potentostat method. In this case, an interface for facilitating measurement setting in the process of using the device may be required to improve user convenience of the potentiostat device.

A technical problem to be solved by the present invention is to provide an improved structure of a potentostat device for improved performance of biodiagnosis, a measuring method, and an interface in the process of using the device for improved convenience of biodiagnosis.

As means for solving the above technical problem, a method for performing biodiagnosis through a potentiostatic electrochemical measuring device according to an aspect of the present invention is performed on a plurality of measurement channels of the potentiostatic electrochemical measuring device. setting measurement items related to potentiostatic electrochemical measurement for each measurement channel; selecting a measurement performance unit to be simultaneously measured for the plurality of measurement channels; generating measurement results for each of the plurality of measurement channels by performing measurement on the plurality of measurement channels according to the measurement execution unit based on the set measurement items; and providing a bio-diagnosis result indicating measurement results for each of the plurality of measurement channels for each measurement channel.

A potentiostatic electrochemical measuring device for biodiagnosis according to another aspect of the present invention includes multi-channel sensors; control unit; and a display, wherein the control unit, in a state where a first user interface (UI) is displayed on the display, when an input to a region for measurement setting included in the first UI is recognized, sets a plurality of measurement channels. Controls the display to display a second UI for setting measurement items for each measurement channel, wherein the second UI includes a measurement sequence setting area, a measurement type setting area, and a measurement parameter setting area. 2 Control the display to display a UI; Control of setting measurement items for each measurement channel for the plurality of measurement channels is performed using the second UI, and one or more measurements are performed for the plurality of measurement channels through the measurement sequence setting area. Set the measurement sequences consisting of for each measurement channel, set the measurement type corresponding to each of the one or more measurements for each measurement channel through the measurement type setting area, and set the one or more measurements through the measurement parameter setting area. It is configured to perform control of setting measurement parameters for each measurement channel according to the measurement type for each of the measurement channels and setting a measurement item for each measurement channel for each of the plurality of measurement channels.

According to the biodiagnosis method using the potentiostatic electrochemical measuring device according to the present invention, multi-channel sensors are provided so that potentiostatic electrochemical measurement of a specimen to be diagnosed can be performed for each of a plurality of channels, At the same time, since measurement results for each channel can be quantified and visualized through a display and provided, even when various types of measurements are required, the time required for measurement can be shortened through multi-channels, and separate numerical/visualization Biodiagnostic results can be easily performed without the process of transferring data to the equipment.

In addition, according to the potentiostatic electrochemical measuring device according to the present invention, the procedure for setting the measurement sequence for each channel in the biodiagnosis process by the potentostat method, the procedure for setting the measurement type of the potentostat, and the Since a user interface (UI) capable of more conveniently performing a procedure for setting measurement parameters may be provided, user convenience of biodiagnosis by the potentostat method may be improved.

1 is a block diagram illustrating elements constituting a potentiostatic electrochemical measurement device for biodiagnosis according to some embodiments.
2 is a diagram for explaining an external structure of a potentiostatic electrochemical measuring device according to some embodiments.
3 is a diagram for explaining a more specific structure of a potentiostatic electrochemical measuring device according to some embodiments.
4 is a flowchart illustrating steps constituting a method of performing biodiagnosis through a potentiostatic electrochemical measurement device according to some embodiments.
5 is a diagram for explaining an interface related to an operation of a potentiostatic electrochemical measuring device and a bio-diagnosis result, according to some embodiments.
6 is a diagram for explaining an interface related to measurement settings of a potentiostatic electrochemical measurement device according to a user's input according to some embodiments.
7 is a diagram for explaining a specific process of performing a biodiagnostic method according to some embodiments.
8 is a diagram for explaining system environment settings of a potentiostatic electrochemical measurement device according to some embodiments.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following description is only for specifying the embodiments, and is not intended to limit or limit the scope of rights according to the present invention. What a person skilled in the art can easily infer from the detailed description and examples of the present invention should be construed as belonging to the scope of the present invention.

The terms used in the present invention have been described as general terms widely used in the technical field related to the present invention, but the meanings of the terms used in the present invention are the intentions of technicians working in the field, the emergence of new technologies, examination standards or precedents. etc. may vary. Some terms may be arbitrarily selected by the applicant, and in this case, the meanings of the arbitrarily selected terms will be described in detail. Terms used in the present invention should be interpreted as meanings reflecting the overall context of the specification, not just dictionary meanings.

Terms such as 'consisting of' or 'comprising' used in the present invention should not be construed as necessarily including all of the components or steps described in the specification, and if some components or steps are not included, and when additional components or steps are further included, it should also be construed as intended from the term.

Terms including ordinal numbers such as 'first' or 'second' used in the present invention may be used to describe various components or steps, but the components or steps should not be limited by ordinal numbers. . Terms containing ordinal numbers should only be construed to distinguish one component or step from other components or steps.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. A detailed description of matters widely known to those skilled in the art will be omitted.

1 is a block diagram illustrating elements constituting a potentiostatic electrochemical measurement device for biodiagnosis according to some embodiments.

Referring to FIG. 1 , a potentiostatic electrochemical measurement device 100 for biodiagnosis may include a measurement signal input/output module 110, multi-channel sensors 120, a controller 130, and a display 140. . However, it is not limited thereto, and other general-purpose elements other than the elements shown in FIG. 1 may be further included in the potentiostatic electrochemical measuring device 100 .

The potentiostatic electrochemical measurement device 100 may refer to a device for performing biodiagnosis by measuring the specimen 200 to be diagnosed using a potentiostat method. The potentiostat method may refer to a potentiostatic electrochemical measurement method that analyzes the behavior of an output current formed as a result of applying a specific input voltage to a specimen.

The specimen 200 to be diagnosed may be a subject of biodiagnosis by the potentiostatic electrochemical measuring device 100 . For example, the specimen 200 to be diagnosed may include human urine and may correspond to various other substances collected from the human body. The results of the biodiagnosis of the specimen 200 to be diagnosed can be used for diagnosing 8 types of cancer or detecting various other body components.

The measurement signal input/output module 110 may be configured to apply an input voltage for constant potential electrochemical measurement to the sample 200 to be diagnosed. The measurement signal input/output module 110 may be controlled by the controller 130 to generate an input voltage having a specific waveform and apply it to the specimen 200 to be diagnosed.

When an input voltage is applied, an output current may be formed from the specimen 200 to be diagnosed, and when the output current is measured by a method such as voltage measurement by the multi-channel sensors 120, a change in the output current over time or By visualizing/digitizing the change according to the input voltage, it is possible to confirm which substances are included in the specimen 200 to be diagnosed.

The multi-channel sensors 120 may be configured to measure an output current flowing through the specimen 200 to be diagnosed by an input voltage. The multi-channel sensors 120 may directly measure the output current or may measure the output current by measuring a voltage formed across a resistor.

The number of multi-channel sensors 120 corresponding to a plurality of channels may be formed. For example, the number of channels of the plurality of measurement channels may be any one of 4 channels, 12 channels, 20 channels, 48 channels, and 96 channels, and the number of sensors of the multi-channel sensors 120 may be determined accordingly. . When the multi-channel sensors 120 have 12 channels, output current detection may be independently performed for each of the 12 channels.

The control unit 130 may be configured to control the measurement signal input/output module 110 to apply voltages separately set for each of a plurality of measurement channels as input voltages for each measurement channel, and the measured signal for each of the plurality of measurement channels It may be configured to generate a plurality of measurement results based on the output current.

The controller 130 may include a memory for storing command words for potentiostatic electrochemical measurement and a processor for executing commands stored in the memory. For example, the memory may be DRAM, SSD, HDD, etc. that stores a computer program or mobile/web application for potentiostatic electrochemical measurement, and the processor may be a CPU, AP, etc. that executes the computer program or mobile/web application. .

The control unit 130 may determine which voltage to apply to the specimen 200 to be diagnosed as an input voltage through the measurement signal input/output module 110 . In particular, since the potentiostatic electrochemical measuring device 100 uses multi-channel sensors 120 rather than a single number of sensors, any measurement channels of the multi-channel sensors 120 are used. Whether or not to apply the input voltage may be set separately.

When the output current corresponding to the input voltage is measured for each of the plurality of measurement channels of the multi-channel sensors 120, the controller 130 performs a plurality of measurement results for the plurality of measurement channels based on each output current. can create them. That is, since a large amount of measurement results required for biodiagnosis can be generated with only one potentiostatic electrochemical measurement device 100 by the multi-channel sensors 120, analysis efficiency can be improved.

Meanwhile, voltages separately set for each of a plurality of measurement channels may be set based on the measurement type of potentiostatic electrochemical measurement. That is, which input voltage to apply to each of the plurality of measurement channels of the multi-channel sensors 120 may be determined according to the measurement type of potentiostatic electrochemical measurement. Accordingly, the measurement signal input/output module 110 may be controlled to apply different input voltages to each of the plurality of measurement channels for each measurement type.

The measurement type of potentiostatic electrochemical measurement is any of CA (ChronoAmperometry), CV (Cycle Voltammetry), LSV (Linear Sweep Voltammetry), NPV (Normal Pulse Voltammetry), DPV (Differential Pulse Voltammetry), and SWV (Square Wave Voltammetry). can be one However, it is not limited thereto, and other types of measurements may also be included in the measurement type of potentiostatic electrochemical measurement.

In biodiagnosis by the potentiostatic electrochemical measurement device 100, various measurement types of potentiostatic electrochemistry for the specimen 200 to be diagnosed depend on what kind of potentiostatic electrochemical measurement is required for a certain type of diagnosis. Measurements can be performed. For example, for diagnosis requiring four types of measurement of CA, CV, LSV, and NPV, input voltages for CA, CV, LSV, and NPV for each of the four measurement channels of the multi-channel sensors 120 this may be authorized.

Meanwhile, the controller 130 may be configured to generate a plurality of measurement results by plotting a change in output current according to a change in output current over time or a change in input voltage according to the type of measurement. . That is, the output current measurement result may be provided in the form of a current-time (I-s) graph or a current-voltage (I-V) graph.

The display 140 may be configured to show a bio-diagnosis result representing a plurality of measurement results for each measurement channel. As described above, the display 140 may display a current-time (I-s) graph or a current-voltage (I-V) graph for each channel according to the measurement type of the potentiostatic electrochemical measurement.

In the potentiostatic electrochemical measurement device 100, in addition to the fact that various types of potentiostatic electrochemical measurements can be performed at once through a plurality of measurement channels of the multi-channel sensors 120, the control unit 130 and the display 140 As a result, a plurality of measurement results for each channel may be digitized and visualized in real time and provided to the user. Therefore, after performing the potentiostatic electrochemical measurement, measurement results for each channel can be provided only by the potentiostatic electrochemical measurement device 100 without post-processing the result, that is, the output current data, in a separate device. Biodiagnosis can be performed more conveniently and quickly.

2 is a diagram for explaining an external structure of a potentiostatic electrochemical measuring device according to some embodiments.

Referring to FIG. 2 , a front structure 21 , a rear structure 22 , a front dimension 23 and a side dimension 24 of a potentiostatic electrochemical measurement device 100 are shown. Referring to the front structure 21, the potentiostatic electrochemical measurement device 100 may include a USB port for connection to a keyboard or mouse, and an HDMI terminal for connection to an external monitor. A monitor as the display 140 may be provided at the top of the front of the potentiostatic electrochemical measurement device 100, and a power switch may be provided at the bottom right.

In addition, referring to the rear structure 22, connector terminals for connecting to the multi-channel sensors 120 may be provided on the rear surface of the potentiostatic electrochemical measurement device 100 in the case of 12 channels, and measurement An I/O connector for connection with the signal input/output module 110, a power cable, and a cooling fan may be provided, and a LAN port for Ethernet connection with the outside may be provided.

In addition, as shown in the front dimension 23 and the side dimension 24, the potentiostatic electrochemical measuring device 100 has horizontal, vertical, and height dimensions of about 20 cm, and is a potentiostatic electrochemical measuring device. The miniaturization of (100) can be implemented, and accordingly, the potentiostatic electrochemical measuring device 100 can be widely used not only in bio research facilities or large hospitals, but also in small and medium-sized hospitals and small laboratories.

3 is a diagram for explaining a more specific structure of a potentiostatic electrochemical measuring device according to some embodiments.

Referring to FIG. 3 , a potentiostatic electrochemical measurement device 300 corresponding to another implementation of the potentiostatic electrochemical measurement device 100 is shown. The potentiostatic electrochemical measurement device 300 may include various additional components in addition to the measurement signal input/output module 310, the multi-channel sensors 320, the controller 330, and the display 340.

Regarding the multi-channel sensors 320, an analyzer and an interface for analyzing and transmitting the analog voltage to the control unit 330 may be additionally provided in the potentiostatic electrochemical measuring device 300, and other power supplies, Wi-Fi A module and storage may be further provided.

4 is a flowchart illustrating steps constituting a method of performing biodiagnosis through a potentiostatic electrochemical measurement device according to some embodiments.

Referring to FIG. 4 , a method 400 of performing biodiagnosis through the potentiostatic electrochemical measuring device 100 may include steps 410 to 440 . However, it is not limited thereto, and other general-purpose steps other than the steps shown in FIG. 4 may be further included in the method 400 for performing biodiagnosis.

The biodiagnosis method 400 may include steps processed time-sequentially by the potentiostatic electrochemical measuring device 100 or the controller 130 . Therefore, even if the content is omitted below, the description of the potentiostatic electrochemical measurement device 100 above can be equally applied to the method 400 for performing biodiagnosis.

In step 410, the potentiostatic electrochemical measurement device 100 may set measurement items related to potentiostatic electrochemical measurement to be performed for each measurement channel for a plurality of measurement channels of the potentiostatic electrochemical measurement device. Setting the measurement items for each measurement channel may include, for a plurality of measurement channels, setting measurement sequences composed of one or more measurements and measurement types corresponding to each of the one or more measurements for each measurement channel. there is. By setting the measurement sequence, the number of measurements to be performed in each measurement channel can be set, and the type of measurement corresponding to the measurement can also be set. For example, a measurement sequence of a first channel among 12 measurement channels may be set in the order of CA-CV-CA-CV-CA-CV.

Setting the measurement items for each measurement channel may further include setting measurement parameters according to the measurement type for each of the one or more measurements. For example, when a plurality of measurements in the measurement sequence are set to CA-CV-CA-CV-CA-CV, measurement parameters may be set for each of the six measurements. Measurement parameters may be composed of different variables according to the type of measurement.

Meanwhile, setting of measurement items such as measurement sequence, measurement type, and measurement parameter may be performed through a user interface of the potentiostatic electrochemical measurement device 100 . In addition, in step 410, when the potentiostatic electrochemical measurement device 100 sets measurement items for each measurement channel, a measurement item for any one measurement channel among the plurality of measurement channels is copied according to a user's input. A copy measurement item may be created, and the copy measurement item may be applied to another measurement channel among the plurality of measurement channels according to a user's input.

In step 420, the potentiostatic electrochemical measurement device 100 may select a measurement execution unit to simultaneously perform measurement on a plurality of measurement channels. The plurality of measurement channels may be divided into a plurality of measurement groups, and each of the plurality of measurement groups may include some channels different from each other among the plurality of measurement channels. For example, 12 measurement channels composed of channels 1 to 12 can be divided into 4 measurement groups including 3 measurement channels, and the 4 measurement groups are channels 1 to 3, channels 4 to 6, It may include channels 7 to 9 and channels 10 to 12.

In this case, all of the plurality of measurement channels may be selected as a measurement execution unit, or each measurement group of the plurality of measurement groups may be selected as a measurement execution unit. For example, by setting the measurement of all channels 1 to 12 to start, potentiostatic electrochemical measurement of all 12 measurement channels can be sequentially performed. Alternatively, by setting measurement to start for a measurement group consisting of channels 1 to 3, potentiostatic electrochemical measurement for channels 1 to 3 can be sequentially performed.

In step 430, the potentiostatic electrochemical measuring device 100 generates measurement results for each of the plurality of measurement channels by performing measurement according to measurement execution units for a plurality of measurement channels based on the set measurement items. can do. More specifically, the potentiostatic electrochemical measurement device 100 may generate a plurality of measurement results by performing a measurement sequence for each measurement channel of a plurality of measurement channels based on measurement parameters. When measurement parameters are set through the user interface, since it is determined what input voltage the control unit 130 applies through the measurement signal input/output module 110 in the potentiostatic electrochemical measurement device 100, the corresponding input voltage A plurality of measurement results may be generated for each measurement channel through measurement of applied and output currents. In addition, when each measurement group of a plurality of measurement groups is selected as the measurement execution unit, measurement results may be generated for each measurement group by continuously performing measurement sequences for measurement channels belonging to the selected measurement group.

In step 440, the potentiostatic electrochemical measurement device 100 may provide biodiagnosis results indicating measurement results for each of a plurality of measurement channels for each measurement channel. When a plurality of measurement results are generated for each measurement channel through the previous steps, the controller 130 may display them on the display 140 for each measurement channel to provide a biodiagnosis result. In this case, a measurement result of a measurement channel to be displayed may also be determined through the user interface.

As described above, in the method 400 for performing biodiagnosis, measurement items, measurement execution units, settings for displaying biodiagnosis results, and the like may be performed using a user interface. For example, a user of the potentiostatic electrochemical measurement device 100 may set a measurement sequence, measurement type, and measurement parameters through an interface provided through the display 140 and an interface such as a mouse/keyboard.

5 is a diagram for explaining an interface related to an operation of a potentiostatic electrochemical measuring device and a bio-diagnosis result, according to some embodiments.

Referring to FIG. 5 , the interface 50 of the potentiostatic electrochemical measuring device 100 includes a start button 51, an all start button 52, a measurement setting button 53, a system setting button 54, and a channel selection A button 55, a measurement sequence selection button 56, a measurement result display area 57, and a log area 58 may be included.

According to the start button 51, potentiostatic electrochemical measurement for related channels, that is, application of an input voltage and measurement of an output current may be started. As shown, potentiostatic electrochemical measurements can be performed in units of three channels. That is, when the potentiostatic electrochemical measurement device 100 generates a plurality of measurement results in step 430, the measurement sequences for three measurement channels are continuously performed using three measurement channels among the plurality of measurement channels as a performance unit. can be done by According to the three-unit measurement, the required measurement time can be shortened when a large amount of measurements are required.

According to the all start button 52, potentiostatic electrochemical measurement of all of a plurality of measurement channels may be started. As in the illustrated case, when a plurality of measurement channels is 12 channels, potentiostatic electrochemical measurement for all 12 measurement channels can be sequentially performed by the all start button 52 .

According to the measurement setting button 53, a new interface is opened, and in step 420, a measurement sequence for each channel, a measurement type for each measurement, and measurement parameters for each measurement type can be set by the user. For the measurement setting button 53, reference may be made to FIG. 6 to be described later. An interface related to overall system settings of the potentiostatic electrochemical measurement device 100 may be opened by the system setting button 54 .

According to the channel selection button 55 , measurement results in the selected measurement channel can be displayed in the measurement result display area 57 . As shown, the result of the potentiostatic electrochemical measurement performed on the selected measurement channel may be displayed in the form of a current-time graph or a current-voltage graph.

According to the measurement sequence selection button 56, a measurement to be displayed in the measurement result display area 57 can be selected from among a plurality of measurements included in the measurement sequence of the selected measurement channel. As shown in the example, when the measurement sequence of channel 1 is composed of CA-CV-LSV-NPV-CA-CA, and the first measurement CA of the measurement sequence is selected, the current-time graph as the measurement result of the first measurement CA may be displayed in the measurement result display area 57 .

On the other hand, as described above, measurement types of potentiostatic electrochemical measurement include CA (ChronoAmperometry), CV (Cycle Voltammetry), LSV (Linear Sweep Voltammetry), NPV (Normal Pulse Voltammetry), DPV (Differential Pulse Voltammetry), and SWV ( Square Wave Voltammetry).

In the log area 58, details of start and abort of measurements for each measurement channel and measurements of the measurement sequence may be recorded. Although not shown in the interface 50, in addition to start buttons such as the start button 51 and the all start button 52, the interface 50 may further include a stop button for stopping measurement in progress.

Meanwhile, in relation to the result graph displayed on the measurement result display area 57, when the potentiostatic electrochemical measurement device 100 provides a biodiagnosis result in step 440, among a plurality of measurement channels and a plurality of measurements A measurement channel selected by a user's input to the potentiostatic electrochemical measurement device 100 and a measurement result graph may be provided. That is, a result graph selected by the channel selection button 55 and the measurement sequence selection button 56 can be displayed in the measurement result display area 57 .

In addition, when the potentiostatic electrochemical measuring device 100 provides a result graph, the change in the output current measured in the 3-electrode system over time or the change in the input voltage applied to the 3-electrode system shows the output current. Changes can be plotted. That is, as illustrated, when the measurement type is CA, an output current-time graph may be generated, and although not shown, when the measurement type is CV, an output current-input voltage graph may be generated.

FIG. 6 is a diagram for explaining an interface for setting measurement items of a potentiostatic electrochemical measurement device according to a user's input according to some embodiments.

Referring to FIG. 6 , an interface 60 related to measurement settings of the potentiostatic electrochemical measurement device 100 is shown. The measurement setting interface 60 may be an interface opened by the measurement setting button 53 of FIG. 5 . The interface 60 may include a measurement channel setting window 61, a measurement sequence setting window 62, a measurement type setting window 63, and a measurement parameter setting window 64.

The measurement sequence, measurement type, and measurement parameters set by the measurement channel setting window 61, the measurement sequence setting window 62, the measurement type setting window 63, and the measurement parameter setting window 64 are the potentiostatic electrochemical measuring device 100 It can be set by a user's input for That is, the measurement sequence, measurement type, and measurement parameters may be set by a user's input through the display 140 and the monitor/keyboard.

According to the measurement channel setting window 61, a measurement sequence, measurement type, and measurement parameters to be set can be selected for which measurement channel among a plurality of measurement channels. Corresponding settings can be set individually for each of the measurement channels. In the illustrated example, it can be confirmed that channel 1 is selected among a total of 20 measurement channels corresponding to 20 channels.

According to the measurement sequence setting window 62, the number of measurements to be performed in the measurement sequence of a corresponding channel can be set by using the [Add] button and the [Delete] button. Meanwhile, the number of the plurality of measurements may be set to 1 to 6 according to a user's input to the potentiostatic electrochemical measurement device 100 . That is, the maximum number of measurements for a measurement sequence may be 6, but the corresponding number may be changed as needed.

According to the measurement type setting window 63, the measurement type of each of the measurements (Measure1, ..., Measure6) constituting the measurement sequence of the selected measurement channel can be set. In addition, according to the measurement parameter setting window 64, measurement parameters can be set for each selected layer type, for example, for the first measurement CA in the measurement sequence of channel 1.

Meanwhile, the measurement parameters may include parameters related to the working electrode WE, the counter electrode CE, and the reference electrode RE constituting the three-electrode system of the potentiostatic electrochemical measurement. That is, the measurement parameters set in the measurement type setting window 63 may correspond to variables in the 3-electrode system, particularly variables related to input voltage and output current.

More specifically, the measurement parameters may include the waveform, magnitude, and duration of an input voltage to be applied to the three-electrode system, which is set by a user's input to the potentiostatic electrochemical measuring device 100 . That is, the measurement parameters may relate to the input voltage applied to the specimen 200 to be diagnosed by the measurement signal input/output module 110 .

In addition, measurement parameters may include values related to output current as well as input voltage. For example, as in the measurement parameter setting window 64, numerical values such as maximum and minimum values for the output current may be set as measurement parameters.

Meanwhile, in a process of setting measurement items for each channel, copy/paste may be applied in which measurement items in one channel are equally applied to other channels. That is, when the potentiostatic electrochemical measurement device 100 sets the measurement parameters in step 420, a value set for any one measurement channel among a plurality of measurement channels is copied according to a user's input to create a copy measurement item. In addition, the copy measurement item may be applied to another measurement channel among a plurality of measurement channels according to a user's input.

According to the above copy/paste method, in the case of multiple channels of 12 channels, 20 channels, or more, the process of setting measurement items for each channel can be simplified. For example, when the same measurement is to be performed through different measurement channels for the specimens 200 to be diagnosed of different patients, the process of setting measurement items can be greatly simplified by the copy/paste method.

According to the user interface (UI) such as the measurement channel setting window 61, the measurement sequence setting window 62, the measurement type setting window 63, and the measurement parameter setting window 64, the potentiostatic electrochemical measuring device 100 for biodiagnosis Since the details for operating the can be easily set, user convenience can be improved.

7 is a diagram for explaining a specific process of performing a biodiagnostic method according to some embodiments.

Referring to FIG. 7 , a detailed process in which the potentiostatic electrochemical measuring device 100 performs biodiagnosis may consist of sections 71 to 75.

Meanwhile, the potentiostatic electrochemical measurement device 100 includes a control unit 76 corresponding to the control unit 130 and the display 140, a measurement unit corresponding to the measurement signal input/output module 110 and the multi-channel sensors 120. (77). The control part 76 and the measurement part 77 may exchange data with each other by Ethernet and local area network as shown, or may be directly connected inside one case as shown in FIG. 3 .

In section 71, a measurement sequence for each channel, a measurement type for each measurement constituting the measurement sequence, and measurement parameters for each measurement type can be set. In section 72, a control signal can be generated according to the setting result. An input voltage may be generated and applied to the specimen 200 to be diagnosed. In section 74, an output current may be measured from the specimen 200 to be diagnosed. In section 75, the output current measured as raw data may be It can be processed and a resulting graph can be provided.

8 is a diagram for explaining system environment settings of a potentiostatic electrochemical measurement device according to some embodiments.

Referring to FIG. 8 , a system setting entry screen 81 , a channel setting screen 82 , and an option setting screen 83 are shown. The system setting entry screen 81, channel setting screen 82, and option setting screen 83 can be opened by the system setting button 54 of FIG.

A password input procedure may be performed on the system setting entry screen 81 . When a correct password is input, a channel setting screen 82 and an option setting screen 83 may be opened.

In the channel setting screen 82, the sensor order assigned to the multi-channel sensors 120 may be reset by channel setting when the potentiostatic electrochemical measuring device 100 is shipped from the factory at the time of production.

In the option setting screen 83, an option on whether to display the value being measured as a two-dimensional graph on the display 140 (Use Plot Display), an option on whether to use an external measurement start signal (Use External Start Signal), option used when cylinder output is connected (Use Up/Down Cylinder Out), option used when cylinder sensor is connected (Use Up/Down Cylinder Sensor), option for automatic re-measurement (Show Auto Replay Option in Main Menu), whether or not to automatically save measurement data (Measuring data auto save), and options for automatically deleting data (Measuring data auto delete) can be set.

In addition, on the option setting screen 83, as an option (DIO Check) related to the measurement signal input/output module 110, an option related to the DIO serial port number (Serial Port of DIO) and an option related to the DIO input/output signal can be set. there is.

Meanwhile, the biodiagnostic method 400 described with reference to FIGS. 4 to 8 may be recorded in a computer-readable recording medium on which at least one program or software including instructions for executing the method is recorded. there is.

Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and floptical disks such as Hardware devices specially configured to store and execute program instructions, such as magneto-optical media, and ROM, RAM, flash memory, and the like, may be included. Examples of program instructions may include high-level language codes that can be executed by a computer using an interpreter or the like as well as machine language codes generated by a compiler.

Although the embodiments of the present invention have been described in detail above, the scope of rights according to the present invention is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present invention described in the following claims are also of the present invention. It should be interpreted as being included in the scope of rights according to

100: potentiostatic electrochemical measuring device 110: measuring signal input/output module
120: multi-channel sensors 130: controller
140: display 200: sample to be diagnosed

Claims (10)

In the potentiostatic electrochemical measuring device for biodiagnosis,
multi-channel sensors;
control unit; and
including a display;
The control unit,
Setting a measurement item for each measurement channel for a plurality of measurement channels when an input is recognized for a measurement setting area included in the first UI while the first user interface (UI) is displayed on the display controlling the display to display a second UI for displaying the second UI, wherein the second UI includes a measurement sequence setting area, a measurement type setting area, and a measurement parameter setting area; ,
Performing control of setting a measurement item for each measurement channel for the plurality of measurement channels using the second UI,
Through the measurement sequence setting area, measurement sequences consisting of one or more measurements for the plurality of measurement channels are set for each measurement channel, and through the measurement type setting area, measurement corresponding to each of the one or more measurements. For each of the plurality of measurement channels, a type is set for each measurement channel, and measurement parameters according to the measurement type are set for each measurement channel for each of the one or more measurements through the measurement parameter setting area. configured to perform a control of setting an item;
The control unit performs control of setting a measurement item for each measurement channel for the plurality of measurement channels using the second UI,
When a first input to the copy area included in the second UI is recognized, copying a measurement item for any one of the plurality of measurement channels to create a copy measurement item;
and apply the copy measurement item to another one of the plurality of measurement channels when the second input to the copy area is recognized. delete According to claim 1,
The potentiostatic electrochemical measuring device, wherein the number of the one or more measurements is set to 1 to 6 by an input to the measurement sequence setting area of the second UI. According to claim 1,
The measurement type is any one of Chronoamperometry (CA), Cycle Voltammetry (CV), Linear Sweep Voltammetry (LSV), Normal Pulse Voltammetry (NPV), Differential Pulse Voltammetry (DPV), and Square Wave Voltammetry (SWV). Electrochemical instrumentation. According to claim 1,
The plurality of measurement channels are divided into a plurality of measurement groups,
Wherein each of the plurality of measurement groups is composed of some channels different from each other among the plurality of measurement channels. According to claim 5,
The first UI further includes an entire measurement start area and a measurement start area for each of the plurality of measurement groups;
The control unit,
The potentiostatic electrochemical measurement device further configured to perform control for selecting a measurement execution unit to be measured simultaneously for the plurality of measurement channels through the measurement start area or the entire measurement start area. According to claim 6,
The control unit, in order to perform control of selecting the measurement performance unit,
When an input for the entire measurement start region is recognized, control is performed to select all of the plurality of measurement channels as the measurement execution unit; or
The potentiostatic electrochemical measurement device further configured to perform control of selecting, as the measurement execution unit, a measurement group corresponding to the measurement start region in which the input is recognized when an input for a measurement start region is recognized. According to claim 7,
The first UI further includes a measurement result display area;
The control unit,
generating measurement results for each of the plurality of measurement channels by performing measurement according to the measurement execution unit for the plurality of measurement channels based on the set measurement items; and
and controlling the display to display a bio-diagnosis result indicating measurement results for each of the plurality of measurement channels for each measurement channel in the measurement result display area of the first UI. According to claim 8,
The control unit,
When each measurement group of the plurality of measurement groups is selected as the measurement execution unit, to generate measurement results for each of the plurality of measurement channels,
A potentiostatic electrochemical measurement device configured to continuously perform measurement sequences for measurement channels belonging to each measurement group of the plurality of measurement groups, thereby generating measurement results for each measurement group for the plurality of measurement groups. According to claim 8,
The first UI further includes a channel selection area and a measurement sequence selection area;
The control unit,
A measurement result graph for a measurement channel and measurement selected by an input to the channel selection area and the measurement sequence selection area among the plurality of measurement channels and the one or more measurements is displayed in the measurement result display area of the first UI. A potentiostatic electrochemical measurement device configured to control the display to display.

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