CN111380819A - Reaction data display method and sample analysis device - Google Patents

Abstract

A reaction data display method and a sample analysis apparatus, comprising: determining a sample and a test item thereof; according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item; determining a comparison product associated with the test item; acquiring reaction data of the comparison product according to the determined comparison product; and displaying the reaction data of the sample and the reaction data of the comparison product on a reaction data interface. According to the invention, the reaction curve of the sample and the reaction curve of the comparison product are displayed on the same interface, so that a user can conveniently compare the reaction curves without switching among a plurality of interfaces, an operator or the user can conveniently compare the reaction data of the sample and the reaction data of the comparison product, and the usability of the instrument is improved.

Description

Reaction data display method and sample analysis device

Technical Field

The present invention relates to a reaction data display method and a sample analyzer.

Background

A sample analyzer is a device for measuring a chemical composition or a physical property of a sample. For example, biochemical analyzers and immunoassay analyzers generally add a reagent to a blood sample, and measure chemical components, concentrations, and the like in the sample by optical means or the like with respect to the sample reacted with the reagent; the specific principle is that the concentration of the tested substance in the tested blood sample is calculated by measuring the change of absorbance after the sample and the reagent are mixed in a period of time and comparing the absorbance generated by the tested blood sample with the change of absorbance after the standard concentration sample with known concentration and the reagent are mixed; it will be appreciated that, due to the different principles and characteristics of the different substances and reagents being tested, it is necessary to test the absorbance changes at different wavelengths or over different times for different items. To facilitate customer viewing, a graph or list of absorbance values at different times for a wavelength for a test item is typically displayed at a sample correlation interface (e.g., a sample test results interface), and the graphical or tabulated absorbance values are typically referred to as reaction data, or reaction curves.

The above is the reaction curve during the sample testing, and the instrument generally involves calibration and quality control during the testing. The calibration is to use a change test of absorbance after a standard concentration sample with known concentration is mixed with the reagent to calibrate the instrument system by detecting the change of the absorbance; wherein a standard concentration sample with a known concentration is called a calibrator, and a change value of absorbance measured after the calibrator is mixed with the reagent is called reaction data of the calibrator (which may be simply referred to as calibration data) or a reaction curve of the calibrator (which may be simply referred to as calibration curve), and is generally displayed on a calibration-related interface, or an operator can view the calibration-related interface.

Similarly, the quality control is used to detect whether the stability of the sample analyzer meets the requirement, and is a change test of absorbance after mixing the quality control material and the reagent, and a change value of absorbance measured after mixing the quality control material and the reagent is referred to as reaction data of the quality control material (which may be referred to as quality control data for short) or a reaction curve of the quality control material (which may be referred to as quality control curve for short), and is generally displayed on a quality control related interface, or an operator can view the reaction curve in the quality control related interface.

In summary, the user can view the reaction curve, the quality control curve and the calibration curve of the sample on the sample correlation interface, the quality control correlation interface and the calibration correlation interface respectively.

In clinical tests, if the concentration of a tested sample is too high, a reagent is expired, or an instrument is abnormal, the absorbance of the tested sample is changed more than expected or unstable. Generally, the sample analysis device can find that the absorbance change of the tested test exceeds a set threshold value through a judgment condition preset by an internal algorithm, and then remind an operator through methods such as alarming or adding an abnormal mark to the result.

Disclosure of Invention

In order to assist a user in judging the cause of a phenomenon in which the change in absorbance of a sample to be measured exceeds an expected value or becomes unstable, the present application provides a reaction data display method and a sample analysis device.

According to a first aspect, there is provided in an embodiment a method of displaying reaction data, comprising:

determining a sample and a test item thereof;

according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item;

determining a comparison product associated with the test item;

acquiring reaction data of the comparison product according to the determined comparison product;

and displaying the reaction data of the sample and the reaction data of the comparison product on a reaction data interface.

In one embodiment, a result list display interface is generated according to each sample to be tested and each test item performed by each sample; wherein the results list display interface includes one or more of a current results display area, an abnormal sample display area, and a historical results display area;

the current result display area comprises a first area for displaying information of a currently tested sample and a second area for displaying information of a corresponding test item; the first region is for receiving an instruction from a user to select a sample; in response to an instruction received at the first area for a user to select a sample, the second area displays information of a test item corresponding to the sample; the second area is used for receiving an instruction of selecting a test item by a user;

the abnormal sample display area comprises a third area and a fourth area, wherein the third area is used for displaying information of a sample of a current abnormal test result, and the fourth area is used for displaying information of a corresponding test item; the third area is used for receiving an instruction of a user to select a sample; in response to an instruction received at a third area for a user to select a sample, the fourth area displays information of a test item corresponding to the sample; the fourth area is used for receiving an instruction of selecting a test item by a user;

the historical result display area comprises a fifth area for displaying information of samples of historical tests and a sixth area for displaying information of corresponding test items; the fifth area is used for receiving an instruction of a user to select a sample; in response to an instruction of a user selecting a sample received at a fifth area, the sixth area displays information of a test item corresponding to the sample; the sixth area is used for receiving an instruction of selecting a test item by a user;

in response to the user's instruction to select the sample and the user's instruction to select the test item, the sample and its test item are determined.

In one embodiment, the result list display interface further includes a reaction data acquisition control for receiving a reaction data acquisition instruction;

and responding to a reaction data acquisition instruction, and acquiring reaction data of the sample relative to the test item according to the determined sample and the test item thereof.

In one embodiment, the reaction data interface is further generated in response to the reaction data acquisition instruction.

In one embodiment, in response to the reaction data acquisition instruction, the reaction data of the sample is also displayed on the generated reaction data interface.

In one embodiment, the reaction data interface further includes a curve comparison control for receiving a curve comparison instruction;

and responding to a curve comparison instruction, and displaying the reaction data of the sample and the reaction data of the comparison product on the reaction data interface.

In one embodiment, in response to a curve comparison instruction, a first control for selecting a comparison product associated with the test item and a second control for selecting the test time of the comparison product are further generated on the reaction data interface; the first control is used for receiving an instruction of selecting a comparison product by a user, and the second control is used for receiving an instruction of selecting test time by the user;

and responding to the instruction of selecting the contrast product by the user and the instruction of selecting the test time by the user, and determining the contrast product associated with the test item and the test time thereof.

In one embodiment, the reaction data interface comprises a curve display area and/or a digital display area; the curve display area displays reaction data in a coordinate drawing point mode; the digital display area displays the reaction data in a digital list mode.

In one embodiment, in the curve display area, the reaction data of the sample and the reaction data of the contrast medium are different in color.

In one embodiment, the reaction data interface further includes a curve adjustment control for receiving a curve adjustment instruction; responding to the curve adjusting instruction, and adjusting the vertical coordinate proportion of the coordinates in the curve display area so as to enable the displayed different reaction data to be complete and clear;

alternatively, the first and second electrodes may be,

and the ordinate proportion of the coordinates in the curve display area is adjusted in a self-adaptive manner, so that the displayed different reaction data are complete and clear.

In one embodiment, parameters needing to be displayed in the reaction data are determined in response to a parameter selection instruction of the reaction data; and displaying parameters to be displayed in the reaction data in a reaction data interface.

In one embodiment, the cursor position of the curved display area is captured; when the cursor position is judged to be located in a preset range of the point drawn in the curve display area, the coordinate value of the point is displayed nearby in a numerical value mode.

In one embodiment, the reaction data interface comprises a plurality of check boxes, and each check box corresponds to one parameter in the reaction data; and checking any check box to show that a corresponding parameter selection instruction in the reaction data is received and the parameter corresponding to the check box needs to be displayed in the reaction data is determined.

In one embodiment, the check boxes include a check box corresponding to the primary wavelength in the response data, a check box corresponding to the secondary wavelength in the response data, and a check box corresponding to the primary wavelength minus the secondary wavelength in the response data.

In one embodiment, the reference substance comprises a standard substance and/or a quality control substance.

According to a second aspect, there is provided in one embodiment a sample analysis device comprising a sample part, a reagent part, an analysis part, a controller and a display;

the sample part is used for bearing a sample to be tested, sucking the sample and then providing the sample to the analysis part;

the reagent part is used for bearing a reagent, and the reagent is sucked and then provided for the analysis part;

the analysis component is used for acquiring and analyzing the reaction data of the sample and the reagent to obtain a test result;

a controller for determining a sample and its test items; according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item; determining a comparison product associated with the test item; acquiring reaction data of the comparison product according to the determined comparison product;

and the display is used for displaying the reaction data of the sample and the reaction data of the contrast product on a reaction data interface.

In one embodiment, the controller generates a result list display interface and controls the display to display according to each sample to be tested and each test item performed by each sample; wherein the results list display interface includes one or more of a current results display area, an abnormal sample display area, and a historical results display area;

the current result display area comprises a first area for displaying information of a currently tested sample and a second area for displaying information of a corresponding test item; the controller receives an instruction of a user to select a sample through a first area; in response to an instruction of a user selecting a sample received at the first area, the controller controls the second area to display information of a test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through the second area;

the abnormal sample display area comprises a third area and a fourth area, wherein the third area is used for displaying information of a sample of a current abnormal test result, and the fourth area is used for displaying information of a corresponding test item; the controller receives an instruction of a user to select a sample through a third area; in response to an instruction of a user selecting a sample received at the third area, the controller controls the fourth area to display information of the test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through the fourth area;

the historical result display area comprises a fifth area for displaying information of samples of historical tests and a sixth area for displaying information of corresponding test items; the controller receives an instruction of selecting a sample by a user through a fifth area; in response to an instruction of a user selecting a sample received at the fifth area, the controller controls the sixth area to display information of the test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through a sixth area;

in response to the user's instruction to select a sample and the user's instruction to select a test item, the controller determines the sample and its test item.

In one embodiment, the result list display interface further includes a reaction data acquisition control, and the controller receives a reaction data acquisition instruction through the reaction data acquisition control;

in response to a reaction data acquisition instruction, the controller acquires reaction data of the sample with respect to the test item according to the determined sample and the test item thereof.

In one embodiment, the controller further generates the reaction data interface in response to the reaction data acquisition instruction.

In one embodiment, in response to the reaction data acquisition instruction, the controller further controls a display to display the reaction data of the sample on the generated reaction data interface.

In one embodiment, the reaction data interface further includes a curve comparison control, and the controller receives a curve comparison instruction through the curve comparison control;

and responding to a curve comparison instruction, and controlling a display to display the reaction data of the sample and the reaction data of the comparison product on the reaction data interface by the controller.

In one embodiment, in response to a curve comparison instruction, the controller further generates a first control for selecting a comparison product associated with the test item and a second control for selecting the test time of the comparison product on the reaction data interface; the controller receives an instruction of selecting a comparison product by a user through the first control and receives an instruction of selecting test time by the user through the second control;

in response to the instruction of the user selecting the contrast product and the instruction of the user selecting the test time, the controller determines the contrast product associated with the test item and the test time thereof.

In one embodiment, the reaction data interface comprises a curve display area and/or a digital display area; the curve display area displays reaction data in a coordinate drawing point mode; the digital display area displays the reaction data in a digital list mode.

In one embodiment, in the curve display area, the reaction data of the sample and the reaction data of the contrast medium are different in color.

In one embodiment, the reaction data interface further includes a curve adjustment control, and the controller receives a curve adjustment instruction through the curve adjustment control; in response to the curve adjusting instruction, the controller adjusts the vertical coordinate proportion of the coordinates in the curve display area so as to enable the displayed different reaction data to be complete and clear; alternatively, the first and second electrodes may be,

the controller adjusts the vertical coordinate proportion of the coordinates in the curve display area in a self-adaptive mode, so that the displayed different reaction data are complete and clear.

In one embodiment, in response to a parameter selection instruction of the reaction data, the controller determines a parameter to be displayed in the reaction data, and controls the display to display the parameter to be displayed in the reaction data on the reaction data interface.

In one embodiment, the controller captures a cursor position of the curve display area, and controls the display to display a coordinate value of a point drawn in the curve display area in a numerical value form in the vicinity of the point when the cursor position is determined to be within a preset range of the point.

In one embodiment, the reaction data interface comprises a plurality of check boxes, and each check box corresponds to one parameter in the reaction data; and any check box is checked to show that the controller receives a selection instruction of the corresponding parameter in the reaction data and determines that the parameter corresponding to the check box needs to be displayed in the reaction data.

In one embodiment, the check boxes include a check box corresponding to the primary wavelength in the response data, a check box corresponding to the secondary wavelength in the response data, and a check box corresponding to the primary wavelength minus the secondary wavelength in the response data.

In one embodiment, the reference substance comprises a standard substance and/or a quality control substance.

According to a third aspect, an embodiment provides a computer-readable storage medium comprising a program executable by a processor to implement a method according to any of the embodiments of the invention.

According to the reaction data display method, the sample analysis device and the computer readable storage medium, the reaction curve of the sample and the reaction curve of the contrast product are displayed on the same interface, so that a user can conveniently compare the reaction curves, the switching among a plurality of interfaces is not needed, an operator or the user can conveniently compare the reaction data of the sample and the reaction data of the contrast product, and the usability of the instrument is improved.

Drawings

FIG. 1 is a schematic structural diagram of a sample analyzer according to an embodiment;

FIG. 2 is a diagram of a results list display interface according to an embodiment;

FIG. 3 is a schematic diagram of a results list display interface of another embodiment;

FIG. 4 is a schematic view of a reaction data interface according to an embodiment;

FIG. 5 is a schematic diagram of a reaction data interface including a curve comparison control according to an embodiment;

FIG. 6 is a schematic view of a reaction data interface of another embodiment;

FIG. 7 is two schematic diagrams of a reaction data interface including a curvilinear display region and/or a numerical display region according to one embodiment;

FIG. 8 is two schematic diagrams of a reaction data interface including a curve adjustment control according to one embodiment;

FIG. 9 is a schematic view of a reaction data interface of yet another embodiment;

FIG. 10 is a schematic view of a reaction data interface of yet another embodiment;

FIG. 11 is a schematic view of a reaction data interface of yet another embodiment;

FIG. 12 is a flowchart of a method for displaying response data according to an embodiment.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

In clinical tests, if the concentration of a tested sample is too high, a reagent is expired, or an instrument is abnormal, the absorbance of the tested sample is changed more than expected or unstable. Generally, the sample analysis device can find that the absorbance change of the tested test exceeds a set threshold value through a judgment condition preset by an internal algorithm, and then remind an operator through methods such as alarming or adding an abnormal mark to the result.

The inventor finds that after receiving the above-mentioned reminding of the instrument, or when looking over the test result, the operator, especially an experienced operator, finds that some parameters or indexes are not in accordance with the rules, the operator can judge the cause by observing and comparing the reaction curve of the test, and take further processing measures, for example, when the reason is judged that the concentration of the sample to be tested is too high, the sample can be diluted and tested, when the reagent is judged to be overdue, a new reagent can be replaced, and when the instrument is judged to be abnormal, the instrument can be maintained. Specifically, the operator typically examines and searches for the cause by comparing the reaction curve of the sample test with the reaction curve of the standard or quality control stored in the instrument, and observing and judging the difference therebetween. In the existing instrument, the test sample management, the quality control management and the calibration management belong to 3 different operation flows, so that the reaction curve, the quality control curve and the calibration curve of the sample are also distributed on different function pages, namely the mentioned sample related interface, the quality control related interface and the calibration related interface; because the operator is to find out the cause of the abnormality of the reaction curve of the sample, the typical operation steps are: after receiving the prompt of the instrument, an operator enters a sample related interface to check the reaction curve of the prompted sample, then exits the sample related interface and enters a quality control or calibration related interface to check the reaction curve of a corresponding quality control product or calibration product, and then switches back and forth to compare the reaction curve of the sample with the corresponding quality control curve or calibration curve; or after entering the relevant interface of quality control or calibration, recording the reaction curve of the corresponding quality control product or calibration product in a photographing or pen recording mode, then cutting back the relevant interface of the sample to check the reaction curve of the sample and comparing the reaction curve with the reaction curve of the quality control product or calibration product recorded by photographing or paper and pen, so as to investigate the reason causing the abnormality of the reaction curve of the sample.

In order to facilitate observation and comparison of a reaction curve of a sample by a user and find out a cause causing abnormality of the reaction curve of the sample, the inventor provides a reaction data display method and a sample analysis device.

Referring to fig. 1, a sample analyzer according to an embodiment of the present invention includes a sample unit 10, a reagent unit 20, an analysis unit 30, a controller 40, and a display 50.

The sample part 10 is used for carrying a sample to be tested, and the sample is sucked and supplied to the analysis part 30. It will be understood that when the sample analysis apparatus is performing a quality control test or a calibration test, the sample block 10 carries a quality control material or a calibration material, since the quality control material and the calibration material are samples of known concentrations.

The reagent unit 20 is used for carrying a reagent, and the reagent is aspirated and supplied to the analysis unit 30.

The analyzing part 30 is used to acquire and analyze reaction data of the sample and the reagent to obtain a test result. It is to be understood that, when the sample analyzer performs a quality control test, the analyzing unit 30 is used to obtain reaction data, or quality control data, of the quality control test of the quality control material and the reagent; similarly, when the sample analysis apparatus performs a calibration test, the analysis component 30 is used to obtain reaction data, or calibration data, of the calibration test of the calibrator and the reagent.

The controller 40 in one embodiment is used to determine the sample and its test items; according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item; determining a comparison product associated with the test item; and acquiring reaction data of the comparison product according to the determined comparison product. In one embodiment, the reference substance comprises a standard substance and/or a quality control substance. It should be noted that, in general, the reference substance, the test item performed by the reference substance, and the test time may uniquely determine one test, and for the determined reference substance and test item, each test time corresponds to one test. The controller 40 thus determines the reference substance to which the test item is associated, in which case the controller 40 may automatically determine one of the reference substances when there are a plurality of reference substances, or determine the reference substance by the relevant selection instruction input by the user; when the controller 40 obtains the reaction data of the contrast according to the determined contrast, the controller 40 may obtain the reaction data of all times according to the determined contrast and the test items performed by the contrast, and then select the reaction data corresponding to the latest test from the reaction data, or randomly select the reaction data corresponding to one test from the reaction data, or the controller 40 may determine the reaction data of the corresponding one test according to the test time selected by the user. The display 50 is used for displaying the reaction data of the sample and the reaction data of the contrast product on a reaction data interface, that is, the display 50 simultaneously displays the reaction data of the sample and the reaction data of the contrast product on one interface, so that an operator can conveniently compare the reaction data of the sample and the reaction data of the contrast product.

How the controller 40 implements the above-described comparison function will be described in detail below.

Referring to fig. 2, in an embodiment, the controller 40 generates a result list display interface according to each sample to be tested and each test item performed by each sample, and controls the display 50 to display the result list display interface. In an embodiment, the result list display interface includes one or more of a current result display area, an abnormal sample display area, and a historical result display area, and in an embodiment, each display area (the current result display area, the abnormal sample display area, and the historical result display area) may be switched in a tab switching manner, and one description is given below for each display area.

The current result display area includes a first area for displaying information of a currently tested sample, and a second area for displaying information of a corresponding test item. The controller 40 can receive an instruction of selecting a sample by a user through the first area, for example, the user selects a sample in the first area through a mouse, etc., and the controller 40 controls the second area to display information of the test items corresponding to the sample, for example, the name and result identification (normal or abnormal, etc.) of each test item performed by the sample, in response to the instruction of selecting the sample by the user received in the first area. The controller 40 receives an instruction of a user to select a test item through the second area, for example, the user selects one test item through a mouse or the like in the second area, and the controller 40 can determine the test item currently selected by the user in response to the instruction of the user to select the test item.

The abnormal sample display area includes a third area for displaying information of a sample of a current abnormal test result, and a fourth area for displaying information of a corresponding test item. The controller 40 receives an instruction of a user selecting a sample through the third area, for example, the user selects one sample at the third area through a mouse or the like, and the controller 40 controls the fourth area to display information of the test item corresponding to the sample in response to the instruction of the user selecting the sample received at the third area. The controller 40 receives an instruction of the user to select a test item through the fourth area, for example, the user selects one test item through a mouse or the like in the fourth area, and the controller 40 can determine the test item currently selected by the user in response to the instruction of the user to select the test item.

The historical result display area includes a fifth area for displaying information of the sample of the historical test, and a sixth area for displaying information of the corresponding test item. The controller 40 receives an instruction of a user selecting a sample through the fifth area, for example, the user selects one sample through a mouse or the like in the fifth area, and the controller 40 controls the sixth area to display information of the test item corresponding to the sample in response to the instruction of the user selecting the sample received in the fifth area. The controller 40 receives an instruction of a user to select a test item through the sixth area, for example, the user selects one test item through a mouse or the like in the sixth area, and the controller 40 can determine the test item currently selected by the user in response to the instruction of the user to select the test item.

It can be seen that the largest difference among the current result display area, the abnormal sample display area and the historical result display area in the result list display interface is that the displayed objects are different, and the displayed objects of the current result display area, the abnormal sample display area and the historical result display area are respectively a currently tested sample, a currently abnormal result sample and a historical test sample. In response to the instruction of the user to select the sample and the instruction of the user to select the test item, the controller 40 determines the sample and the test item thereof. For example, the user may select a sample and its test items in the current result display area by a mouse or the like, and in response to an instruction of the user to select the sample and an instruction of the user to select the test items, the controller 40 determines the sample and its test items; for example, the user may select a sample and its test items in the abnormal sample display area by using a mouse or the like, and in response to an instruction for selecting the sample by the user and an instruction for selecting the test items by the user, the controller 40 determines the sample and its test items; for example, the user may select a sample and its test items in the history result display area by a mouse or the like, and the controller 40 determines the sample and its test items in response to an instruction of the user to select the sample and an instruction of the user to select the test items. It should be noted that fig. 2 is a schematic diagram of the result list display interface, which includes the previous result display area, the abnormal sample display area, and the historical result display area, and switches to the abnormal sample display area for displaying currently, the user selects the sample numbered 6 (which is highlighted), and displays two Test items Test1 and Test2 performed by the sample in the fourth area, and the user selects the Test item Test2 (which is highlighted).

It can be seen that human interaction is enabled through the results list display interface, enabling the controller 40 to determine the sample and its test items.

Referring to fig. 3, in an embodiment, the result list display interface generated by the controller 40 may further include a reaction data obtaining control 41, and the controller 40 may receive a reaction data obtaining instruction through the reaction data obtaining control 41. For example, the reaction data obtaining control 41 is a button, and the user can click the button through a mouse or a keyboard shortcut key, that is, the user inputs a reaction data obtaining instruction. In response to the reaction data acquiring instruction, the controller 40 acquires reaction data of the sample with respect to the test item according to the determined sample and the test item thereof. The acquired reaction data may be displayed in a result list display interface, or another interface may be generated to display the reaction data. For example, referring to fig. 4, in one embodiment, in response to the reaction data obtaining instruction, the controller 40 further generates a reaction data interface; further, in response to the reaction data acquisition command, the controller 40 in one embodiment also controls the display 50 to display the reaction data of the sample on the generated reaction data interface.

As described above, the reaction data interface is used to display the reaction data of the sample, and the reaction data interface is described in detail below.

Referring to fig. 5, in an embodiment, the reaction data interface generated by the controller 40 may further include a curve comparison control 42, and the controller 40 may receive a curve comparison instruction through the curve comparison control 42. For example, the curve comparison control 42 is a button that can be clicked by a user through a mouse or a keyboard shortcut, i.e., the user inputs a curve comparison command. In response to the curve comparison instruction, the controller 40 controls the display 50 to display the reaction data of the sample and the reaction data of the comparison product on the reaction data interface, for example, the controller 40 displays the reaction data of the comparison product on the basis of the reaction data interface displaying the reaction data of the sample. In this process, after determining the sample and its test items, the controller 40 may automatically determine the contrast associated with the test items, and if there are multiple contrast, the controller 40 may automatically determine one of the multiple contrast, or determine the contrast by the relevant selection instruction input by the user; when the controller 40 obtains the reaction data of the contrast according to the determined contrast, the controller 40 may obtain the reaction data of all times according to the determined contrast and the test items performed by the contrast, and then select the reaction data corresponding to the latest test from the reaction data, or randomly select the reaction data corresponding to one test from the reaction data, or the controller 40 may determine the reaction data of the corresponding one test according to the test time selected by the user. The following is an example of a user manually selecting a control and a test time. For example, referring to fig. 6, in an embodiment, in response to the curve comparison instruction, the controller 40 further generates a first control 43 for selecting a comparison product associated with the test item and a second control 44 for selecting the test time of the comparison product on the reaction data interface; wherein the controller 40 receives an instruction from the user to select the contrast via the first control 43 and receives an instruction from the user to select the testing time via the second control 44. For example, the first control 43 is a drop-down selection box for allowing the user to select a contrast; the second control 44 is also a drop-down selection box that allows the user to select the test time for the control. It should be noted that, since the controller 40 determines the sample and the test item thereof, the range of the contrast media that can be selected by the user in the pull-down box of the first control 43 can also be determined according to the test item, and similarly, the times that can be selected by the user in the pull-down box of the second control 44 can also be determined according to the test item and the selected contrast media. In response to the user instruction to select a reference and the user instruction to select a test time, the controller 40 determines the reference associated with the test item and its test time. The controller 40 may then obtain reaction data for the control and control the display 50 to display on the reaction data interface. It should be noted that fig. 6 shows the reaction data of the sample and the reaction data of the selected quality control material.

A detailed description will be given below of how the controller 40 controls the display 50 to display, or how the display 50 displays.

The reaction data interfaces in fig. 4 to 6 all show the reaction data as plotted points. In one embodiment, the response data interface displayed by the display 50 may include a curve display area and/or a number display area. For example, the curve display area and the digital display area can be switched in the calibration data interface in the form of tabs, or the curve display area and the digital display area can be simultaneously displayed in the reaction data interface for switching — for example, the curve display area is located in the upper half part of the reaction data interface, and the digital display area is located in the lower half part of the reaction data interface. Fig. 7 shows an example of switching the curve display area and the numerical display area in the calibration data interface in the form of tabs, in which fig. 7(a) shows the curve display area selected and fig. 7(b) shows the numerical display area selected, in which the left side shows the reaction data of the sample and the right side shows the reaction data of the selected quality control material.

In one embodiment, the curve display area displays the response data in the form of plotted points, as shown in FIG. 7(a) above. For example, the reaction data is plotted with the lighting cycle as the abscissa and the absorbance as the ordinate. In order to distinguish the reaction data of the sample from the reaction data of the comparison product, in an embodiment, in the curve display area, the color of the reaction data of the sample is different from that of the reaction data of the comparison product, for example, the point where the reaction data of the sample is plotted is one color, and the point where the reaction data of the comparison product is plotted is another color.

Sometimes, the reaction data of the sample and the contrast medium are overlapped in a staggered way when displayed in the curve display area, and the user can be influenced to view the data. . Therefore, in some embodiments, referring to fig. 8, the response data interface further includes a curve adjustment control 45, and the controller 40 receives the curve adjustment command through the curve adjustment control 45, for example, the curve adjustment control 45 is a button, and when clicked, the controller 40 receives the curve adjustment command. In response to the curve adjustment command, the controller 40 adjusts the ordinate scale of the coordinates in the curve display area so that the different response data displayed by the display 50 are complete and clear, e.g., do not visually coincide together. It should be noted that, here, the controller 40 adjusts the ordinate scale of the coordinates in the curve display area, there may be at least two implementation manners, the first manner is: only one ordinate is present in the curve display area, and the controller 40 adjusts the ratio of the ordinate; the second mode is as follows: the controller 40 controls the display 50 to display at least one vertical coordinate by regenerating and controlling the curve display area to have only one vertical coordinate originally, so that the reaction data of the sample and the reaction data of the contrast respectively correspond to different vertical coordinates; in a specific implementation, after clicking the curve adjustment control 42, the controller 40 adjusts the ordinate scale of the coordinate in the curve display area — for example, as shown in fig. 8(a), automatically adjusts the scale of a currently unique ordinate, or, for example, as shown in fig. 8(b), generates a new ordinate, generally, the scale of the new ordinate is different from the scale of the existing ordinate; or a pop-up box may be generated for the user to input the ordinate scale of the coordinates in the curve display area, and the controller 40 adjusts the ordinate scale of the coordinates in the curve display area according to the ordinate scale input by the user, for example, the current unique ordinate scale is adjusted according to the ordinate scale input by the user, or a new ordinate is generated according to the ordinate scale input by the user, so that the user can adjust the ordinate scale to the desired scale, and the reaction data of the sample and the contrast sample is displayed completely and clearly. In other embodiments, the controller 40 can adaptively adjust the ordinate-scale of the coordinates in the curve display area to complete and clearly display the different reaction data, i.e. to complete and clearly display the reaction data of the sample and the contrast, and similarly, there can be at least two implementations where the controller 40 can adaptively adjust the ordinate-scale of the coordinates in the curve display area, the first implementation: only one vertical coordinate is arranged in the curve display area, and the controller 40 adaptively adjusts the proportion of the vertical coordinate; the second mode is as follows: the curve display area originally has only one ordinate, and the controller 40 causes the reaction data of the sample and the reaction data of the reference substance to correspond to different ordinates, respectively, by regenerating and controlling the display 50 to display at least one ordinate.

In some embodiments, the reaction data includes a plurality of parameters, such as absorbance for the parameter primary wavelength, absorbance for the parameter secondary wavelength, and absorbance for the parameter primary wavelength minus the parameter secondary wavelength. Therefore, in one embodiment, the controller 40 is further responsive to a parameter selection command for the reaction data to determine the parameters to be displayed in the reaction data; the controller 40 then controls the display 50 to display the parameters to be displayed in the reaction data interface, such as the curve display area. Referring to fig. 9, in an embodiment, the reaction data interface may include a plurality of check boxes, each of which corresponds to a parameter in the reaction data, and any check box is checked to indicate that the controller 40 receives a selection instruction for the corresponding parameter in the reaction data and determines that the parameter corresponding to the check box needs to be displayed in the reaction data. For example, the check boxes can include a check box corresponding to the primary wavelength in the reaction data, a check box corresponding to the secondary wavelength in the reaction data, and a check box corresponding to the primary wavelength minus the secondary wavelength in the reaction data. In order to allow the user to visually see the specific value of each point on the curve display area where the reaction data is plotted, the controller 40 in one embodiment also captures the cursor position of the curve display area, and when the cursor position is determined to be within a predetermined range of the plotted point in the curve display area, the controller 50 is controlled to display the coordinate value of the point in the form of a numerical value in the vicinity of the point, for example, fig. 10 is an example.

In one embodiment, the digital display area displays the response data in a digital list. For example, the reaction data is displayed below the corresponding column with the lighting cycle in one column and the absorbance in one column. Similarly, in one embodiment, the controller 40 is further responsive to a parameter selection command for the reaction data to determine the parameters to be displayed in the reaction data; the controller 40 controls the display to display the parameters to be displayed in the reaction data interface, such as the digital display area. FIG. 11 shows an example in which only the absorbance of the dominant wavelength in the reaction data is shown.

The above are some of the illustrations of the display 50 displaying the response data. The user can search the cause of the abnormal reaction data of the sample by comparing the reaction data of the sample and the contrast product on the same interface.

The embodiment of the invention also discloses a reaction data display method. Referring to fig. 12, a method for displaying response data according to an embodiment includes steps 100 to 140, which are described in detail below.

Step 100: the sample and its test items are determined.

Referring back to fig. 2, in an embodiment, step 100 may provide a result list display interface for the user to select the sample and the test item, and step 100 may determine the sample and the test item in response to the instruction of the user to select the sample and the instruction of the user to select the test item. For example, in one embodiment, step 100 generates a result list display interface based on each sample tested and each test item performed by each sample. In an embodiment, the result list display interface includes one or more of a current result display area, an abnormal sample display area, and a historical result display area, and in an embodiment, each display area (the current result display area, the abnormal sample display area, and the historical result display area) may be switched in a tab switching manner, and one description is given below for each display area.

The current result display area includes a first area for displaying information of a currently tested sample, and a second area for displaying information of a corresponding test item. The first area is used to receive an instruction of selecting a sample by a user, for example, the user selects a sample in the first area by a mouse, etc., and step 100 displays information of the test items corresponding to the sample, for example, names and result identifications (normal or abnormal, etc.) of the test items performed by the sample, in the second area in response to the instruction of selecting the sample by the user received in the first area. The second area is used for receiving an instruction of selecting a test item by a user, for example, the user selects a test item in the second area by a mouse or the like, and step 100 can determine the test item currently selected by the user in response to the instruction of selecting the test item by the user.

The abnormal sample display area includes a third area for displaying information of a sample of a current abnormal test result, and a fourth area for displaying information of a corresponding test item. The third area is used to receive an instruction of selecting a sample by a user, for example, the user selects a sample in the third area by a mouse, and step 100 displays information of the test item corresponding to the sample in the fourth area in response to the instruction of selecting the sample by the user received in the third area. The fourth area is used for receiving an instruction of selecting a test item by a user, for example, the user selects a test item in the fourth area by a mouse or the like, and step 100 can determine the test item currently selected by the user in response to the instruction of selecting the test item by the user.

The historical result display area includes a fifth area for displaying information of the sample of the historical test, and a sixth area for displaying information of the corresponding test item. The fifth area is used for receiving an instruction of selecting a sample by a user, for example, the user selects a sample in the fifth area by a mouse, and step 100 displays information of the test item corresponding to the sample in the sixth area in response to the instruction of selecting the sample by the user received in the fifth area. The sixth area is used for receiving an instruction of selecting a test item by a user, for example, the user selects a test item in the sixth area by a mouse or the like, and step 100 can determine the test item currently selected by the user in response to the instruction of selecting the test item by the user.

It can be seen that the largest difference among the current result display area, the abnormal sample display area and the historical result display area in the result list display interface is that the displayed objects are different, and the displayed objects of the current result display area, the abnormal sample display area and the historical result display area are respectively a currently tested sample, a currently abnormal result sample and a historical test sample. In response to the user's instruction to select a sample and the user's instruction to select a test item, step 100 determines the sample and its test items. For example, the user may select a sample and its test items in the current result display area by using a mouse or the like, and in response to an instruction of selecting the sample by the user and an instruction of selecting the test items by the user, step 100 determines the sample and its test items; for example, the user may select a sample and its test items in the abnormal sample display area by using a mouse or the like, and in response to an instruction of selecting the sample by the user and an instruction of selecting the test items by the user, the step 100 determines the sample and its test items; for example, the user may select a sample and its test items in the history result display area by using a mouse or the like, and in response to an instruction of the user to select the sample and an instruction of the user to select the test items, the step 100 determines the sample and its test items.

It can be seen that human-computer interaction is enabled through the results list display interface, such that step 100 determines the sample and its test items.

Step 110: and acquiring reaction data of the sample relative to the test item according to the determined sample and the test item thereof.

In one embodiment, step 110 is responsive to a reaction data obtaining instruction, and obtains reaction data of the sample with respect to the test item according to the determined sample and the test item thereof. For example, referring back to fig. 3, in an embodiment, the result list display interface further includes a reaction data obtaining control 41, configured to receive a reaction data obtaining instruction, so that step 110 can receive the reaction data obtaining instruction through the reaction data obtaining control 41. For example, the reaction data obtaining control 41 is a button, and the user can click the button through a mouse or a keyboard shortcut key, that is, the user inputs a reaction data obtaining instruction. The acquired reaction data may be displayed in a result list display interface, or another interface may be generated to display the reaction data. For example, referring back to fig. 4, in one embodiment, in response to the reaction data obtaining instruction, step 110 further generates a reaction data interface; further, in response to the reaction data acquisition command, step 110 also controls display 50 to display the reaction data of the sample on the generated reaction data interface in one embodiment.

Step 120: and determining a comparison product associated with the test item.

Step 130: and acquiring reaction data of the comparison product according to the determined comparison product. It should be noted that, in general, the reference substance, the test item performed by the reference substance, and the test time may uniquely determine one test, and for the determined reference substance and test item, each test time corresponds to one test. Step 120 therefore determines the contrast products associated with the test items, wherein when there are a plurality of contrast products, step 120 may automatically determine one of the contrast products, or determine the contrast product by the relevant selection instruction input by the user; when the step 130 obtains the reaction data of the comparison product according to the determined comparison product, the step 130 may obtain the reaction data of all times according to the determined comparison product and the test items performed by the comparison product, and then select the reaction data corresponding to the latest test from the reaction data, or randomly select the reaction data corresponding to one test from the reaction data, or the step 130 determines the reaction data of the corresponding one test according to the test time selected by the user.

Step 140: and displaying the reaction data of the sample and the reaction data of the comparison product on a reaction data interface.

Referring back to fig. 5, in an embodiment, the reaction data interface generated in step 110 may further include a curve comparison control 42, and step 140 may receive a curve comparison instruction through the curve comparison control 42. For example, the curve comparison control 42 is a button that can be clicked by a user through a mouse or a keyboard shortcut, i.e., the user inputs a curve comparison command. In response to the curve comparison instruction, step 140 controls the reaction data of the sample and the reaction data of the comparison product to be displayed on the reaction data interface, for example, step 140 displays the reaction data of the comparison product on the basis of the reaction data interface displaying the reaction data of the sample. In this process, step 110 may, after determining the sample and its test items, cause step 120 to automatically determine the contrast associated with the test items, and if there are a plurality of contrast, step 120 may automatically determine one of them, or determine the contrast by the relevant selection instruction input by the user; when the step 130 obtains the reaction data of the comparison product according to the determined comparison product, the step 130 may obtain the reaction data of all times according to the determined comparison product and the test items performed by the comparison product, and then select the reaction data corresponding to the latest test from the reaction data, or randomly select the reaction data corresponding to one test from the reaction data, or the step 130 determines the reaction data of the corresponding one test according to the test time selected by the user. The following is an example of a user manually selecting a control and a test time. For example, referring back to fig. 6, in an embodiment, in response to the curve comparison instruction, the step 120 further generates a first control 43 for selecting a comparison product associated with the test item and a second control 44 for selecting the test time of the comparison product on the reaction data interface; wherein step 120 receives an instruction of selecting the contrast product by the user through the first control 43 and receives an instruction of selecting the testing time by the user through the second control 44. For example, the first control 43 is a drop-down selection box for allowing the user to select a contrast; the second control 44 is also a drop-down selection box that allows the user to select the test time for the control. It should be noted that, since the sample and the test item thereof are determined in step 100, the range of the contrast media that can be selected by the user in the pull-down box of the first control 43 can also be determined according to the test item, and similarly, the times that can be selected by the user in the pull-down box of the second control 44 can also be determined according to the test item and the selected contrast media. In response to the user instruction to select the contrast media and the user instruction to select the testing time, step 120 determines the contrast media associated with the testing item and the testing time thereof. Step 130 may then acquire reaction data of the contrast, and step 140 displays the acquired reaction data of the contrast on the reaction data interface.

The following describes a mode of displaying reaction data by the reaction data display method.

In one embodiment, the reaction data interface may include a curvilinear display region and/or a numerical display region. For example, the curve display area and the digital display area can be switched in the calibration data interface in the form of tabs, or the curve display area and the digital display area can be simultaneously displayed in the reaction data interface for switching — for example, the curve display area is located in the upper half part of the reaction data interface, and the digital display area is located in the lower half part of the reaction data interface. Fig. 7 shows an example of switching the curve display area and the numerical display area in the calibration data interface in the form of tabs, in which fig. 7(a) shows the curve display area selected and fig. 7(b) shows the numerical display area selected, in which the left side shows the reaction data of the sample and the right side shows the reaction data of the selected quality control material.

In one embodiment, the curve display area displays the response data in the form of plotted points, as shown in FIG. 7(a) above. For example, the reaction data is plotted with the lighting cycle as the abscissa and the absorbance as the ordinate. In order to distinguish the reaction data of the sample from the reaction data of the comparison product, in an embodiment, in the curve display area, the color of the reaction data of the sample is different from that of the reaction data of the comparison product, for example, the point where the reaction data of the sample is plotted is one color, and the point where the reaction data of the comparison product is plotted is another color.

Sometimes, the reaction data of the sample and the contrast medium are overlapped in a staggered way when displayed in the curve display area, and the user can be influenced to view the data. Therefore, in some embodiments, referring back to fig. 8, the reaction data interface further includes a curve adjustment control 45, and step 140 receives the curve adjustment instruction through the curve adjustment control 45, for example, the curve adjustment control 45 is a button, and when clicked, step 140 receives the curve adjustment instruction. Step 140 adjusts the ordinate scale of the coordinates in the curve display area in response to the curve adjustment instruction so that the displayed different response data are complete and clear, e.g., not visually superimposed together. It should be noted that, here, the step 140 adjusts the ordinate-ordinate ratio of the coordinates in the curve display area, there may be at least two implementation manners, the first manner is: only one ordinate is present in the curve display area, and step 140 adjusts the scale of the ordinate; the second mode is as follows: only one ordinate is originally in the curve display area, and the step 140 respectively corresponds the reaction data of the sample and the reaction data of the contrast product to different ordinates by regenerating and displaying at least one other ordinate; in a specific implementation, after the curve adjustment control 42 is clicked, step 140 adjusts the vertical coordinate ratio of the coordinates in the curve display area — for example, as shown in fig. 8(a), step 140 automatically adjusts the ratio of a currently unique vertical coordinate, or, as shown in fig. 8(b), step 140 regenerates a new vertical coordinate, generally, the ratio of the new vertical coordinate is different from the ratio of the existing vertical coordinate; or a pop-up box may be generated for the user to input the ordinate scale of the coordinates in the curve display area, and the step 140 adjusts the ordinate scale of the coordinates in the curve display area according to the ordinate scale input by the user — for example, the step 140 adjusts the current unique ordinate scale according to the ordinate scale input by the user, or the step 140 regenerates a new ordinate according to the ordinate scale input by the user, so that the user can adjust the ordinate scale to the desired scale, thereby completely and clearly displaying the reaction data of the sample and the contrast. Thus, in one embodiment, step 140 can adaptively adjust the ordinate-scale of the coordinates in the curve display area to complete and clearly display the different reaction data, i.e. to complete and clearly display the reaction data of the sample and the contrast, and similarly, there can be at least two implementations where step 140 can adaptively adjust the ordinate-scale of the coordinates in the curve display area, the first implementation: only one ordinate is in the curve display area, and the proportion of the ordinate is adaptively adjusted in step 140; the second mode is as follows: in the curve display area, only one ordinate step 140 originally generates and displays at least one other ordinate, so that the reaction data of the sample and the reaction data of the reference substance correspond to different ordinates, respectively.

In some embodiments, the reaction data includes a plurality of parameters, such as absorbance for the parameter primary wavelength, absorbance for the parameter secondary wavelength, and absorbance for the parameter primary wavelength minus the parameter secondary wavelength. Therefore, in one embodiment, step 110 and/or step 140 further responds to the parameter selection instruction of the reaction data to determine the parameters required to be displayed in the reaction data; step 110 and/or step 140 further controls the display 50 to display the parameters to be displayed in the reaction data interface, such as the curve display area. Referring back to fig. 9, in an embodiment, the reaction data interface may include a plurality of check boxes, each check box corresponds to a parameter in the reaction data, and any check box is checked to indicate that step 110 and/or step 140 receives a selection instruction for the corresponding parameter in the reaction data, and determines that the parameter corresponding to the check box needs to be displayed in the reaction data. For example, the check boxes can include a check box corresponding to the primary wavelength in the reaction data, a check box corresponding to the secondary wavelength in the reaction data, and a check box corresponding to the primary wavelength minus the secondary wavelength in the reaction data. In order to allow the user to visually see the specific value of each point on the curve display area where the reaction data is plotted, in one embodiment, step 110 and/or step 140 further captures the cursor position of the curve display area, and when the cursor position is determined to be within a preset range of the plotted point in the curve display area, the coordinate value is displayed in the form of a numerical value in the vicinity of the plotted point, for example, fig. 10 is an example.

In one embodiment, the digital display area displays the response data in a digital list. For example, the reaction data is displayed below the corresponding column with the lighting cycle in one column and the absorbance in one column. Similarly, in an embodiment, step 110 and/or step 140 is further responsive to a parameter selection instruction of the reaction data to determine a parameter to be displayed in the reaction data; step 110 and/or step 140 further displays the parameters to be displayed in the reaction data interface, such as a digital display area. As shown in FIG. 11, the absorbance of the dominant wavelength in the reaction data is shown.

According to the invention, the reaction curve of the sample and the reaction curve of the comparison product are displayed on the same interface, so that a user can conveniently compare the reaction curves without switching among a plurality of interfaces, an operator or the user can conveniently compare the reaction data of the sample and the reaction data of the comparison product, and the usability of the instrument is improved.

Reference is made herein to various exemplary embodiments. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope hereof. For example, the various operational steps, as well as the components used to perform the operational steps, may be implemented in differing ways depending upon the particular application or consideration of any number of cost functions associated with operation of the system (e.g., one or more steps may be deleted, modified or incorporated into other steps).

In the above embodiments, the implementation may be wholly or partially realized by software, hardware, firmware, or any combination thereof. Additionally, as will be appreciated by one skilled in the art, the principles herein may be reflected in a computer program product on a computer readable storage medium, which is pre-loaded with computer readable program code. Any tangible, non-transitory computer-readable storage medium may be used, including magnetic storage devices (hard disks, floppy disks, etc.), optical storage devices (CD-ROMs, DVDs, Blu Ray disks, etc.), flash memory, and/or the like. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including means for implementing the function specified. The computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified.

While the principles herein have been illustrated in various embodiments, many modifications of structure, arrangement, proportions, elements, materials, and components particularly adapted to specific environments and operative requirements may be employed without departing from the principles and scope of the present disclosure. The above modifications and other changes or modifications are intended to be included within the scope of this document.

The foregoing detailed description has been described with reference to various embodiments. However, one skilled in the art will recognize that various modifications and changes may be made without departing from the scope of the present disclosure. Accordingly, the disclosure is to be considered in an illustrative and not a restrictive sense, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. However, the benefits, advantages, solutions to problems, and any element(s) that may cause any element(s) to occur or become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims. As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, system, article, or apparatus. Furthermore, the term "coupled," and any other variation thereof, as used herein, refers to a physical connection, an electrical connection, a magnetic connection, an optical connection, a communicative connection, a functional connection, and/or any other connection.

Those skilled in the art will recognize that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention.

Claims (31)

1. A method of displaying response data, comprising:

determining a sample and a test item thereof;

according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item;

determining a comparison product associated with the test item;

acquiring reaction data of the comparison product according to the determined comparison product;

and displaying the reaction data of the sample and the reaction data of the comparison product on a reaction data interface.

2. The reaction data display method according to claim 1, wherein a result list display interface is generated based on each sample to be tested and each test item performed by each sample; wherein the results list display interface includes one or more of a current results display area, an abnormal sample display area, and a historical results display area;

the current result display area comprises a first area for displaying information of a currently tested sample and a second area for displaying information of a corresponding test item; the first region is for receiving an instruction from a user to select a sample; in response to an instruction received at the first area for a user to select a sample, the second area displays information of a test item corresponding to the sample; the second area is used for receiving an instruction of selecting a test item by a user;

the abnormal sample display area comprises a third area and a fourth area, wherein the third area is used for displaying information of a sample of a current abnormal test result, and the fourth area is used for displaying information of a corresponding test item; the third area is used for receiving an instruction of a user to select a sample; in response to an instruction received at a third area for a user to select a sample, the fourth area displays information of a test item corresponding to the sample; the fourth area is used for receiving an instruction of selecting a test item by a user;

the historical result display area comprises a fifth area for displaying information of samples of historical tests and a sixth area for displaying information of corresponding test items; the fifth area is used for receiving an instruction of a user to select a sample; in response to an instruction of a user selecting a sample received at a fifth area, the sixth area displays information of a test item corresponding to the sample; the sixth area is used for receiving an instruction of selecting a test item by a user;

in response to the user's instruction to select the sample and the user's instruction to select the test item, the sample and its test item are determined.

3. The reaction data display method of claim 2, wherein the result list display interface further comprises a reaction data acquisition control for receiving a reaction data acquisition instruction;

and responding to a reaction data acquisition instruction, and acquiring reaction data of the sample relative to the test item according to the determined sample and the test item thereof.

4. The reaction data display method of claim 3, wherein the reaction data interface is further generated in response to the reaction data acquisition instruction.

5. The reaction data display method of claim 4, wherein in response to the reaction data acquisition instruction, the reaction data of the sample is also displayed on the generated reaction data interface.

6. The reaction data display method according to any one of claims 1 to 5, wherein the reaction data interface further comprises a curve comparison control for receiving a curve comparison instruction;

and responding to a curve comparison instruction, and displaying the reaction data of the sample and the reaction data of the comparison product on the reaction data interface.

7. The reaction data display method of claim 6, further generating a first control for selecting a contrast associated with the test item and a second control for selecting a test time of the contrast in the reaction data interface in response to a curve comparison instruction; the first control is used for receiving an instruction of selecting a comparison product by a user, and the second control is used for receiving an instruction of selecting test time by the user;

and responding to the instruction of selecting the contrast product by the user and the instruction of selecting the test time by the user, and determining the contrast product associated with the test item and the test time thereof.

8. The reaction data display method of claim 1, wherein the reaction data interface comprises a curve display area and/or a number display area; the curve display area displays reaction data in a coordinate drawing point mode; the digital display area displays the reaction data in a digital list mode.

9. The reaction data display method of claim 8, wherein the reaction data of the sample is different in color from the reaction data of the control in the curve display area.

10. The reaction data display method of claim 8, wherein the reaction data interface further comprises a curve adjustment control for receiving a curve adjustment instruction; responding to the curve adjusting instruction, and adjusting the vertical coordinate proportion of the coordinates in the curve display area so as to enable the displayed different reaction data to be complete and clear;

alternatively, the first and second electrodes may be,

and the ordinate proportion of the coordinates in the curve display area is adjusted in a self-adaptive manner, so that the displayed different reaction data are complete and clear.

11. The reaction data display method of claim 8, wherein:

responding to a parameter selection instruction of the reaction data, and determining parameters needing to be displayed in the reaction data;

and displaying parameters to be displayed in the reaction data in a reaction data interface.

12. The reaction data display method of claim 11, wherein:

capturing the cursor position of the curve display area;

when the cursor position is judged to be located in a preset range of the point drawn in the curve display area, the coordinate value of the point is displayed nearby in a numerical value mode.

13. A reaction data display method according to claim 11 or 12, wherein the reaction data interface comprises a plurality of check boxes, each check box corresponding to a parameter in the reaction data; and checking any check box to show that a corresponding parameter selection instruction in the reaction data is received and the parameter corresponding to the check box needs to be displayed in the reaction data is determined.

14. The reaction data display method according to claim 11, wherein the check boxes include a check box corresponding to a primary wavelength in the reaction data, a check box corresponding to a secondary wavelength in the reaction data, and a check box corresponding to a primary wavelength minus a secondary wavelength in the reaction data.

15. The method of claim 1, wherein the reference substance comprises a standard substance and/or a quality control substance.

16. A sample analysis apparatus, comprising: a sample component, a reagent component, an analysis component, a controller, and a display;

the sample part is used for bearing a sample to be tested, sucking the sample and then providing the sample to the analysis part;

the reagent part is used for bearing a reagent, and the reagent is sucked and then provided for the analysis part;

the analysis component is used for acquiring and analyzing the reaction data of the sample and the reagent to obtain a test result;

a controller for determining a sample and its test items; according to the determined sample and the test item thereof, acquiring reaction data of the sample about the test item; determining a comparison product associated with the test item; acquiring reaction data of the comparison product according to the determined comparison product;

and the display is used for displaying the reaction data of the sample and the reaction data of the contrast product on a reaction data interface.

17. The sample analyzer of claim 16, wherein the controller generates a result list display interface and controls the display to display, based on each sample being tested and each test item being performed by each sample; wherein the results list display interface includes one or more of a current results display area, an abnormal sample display area, and a historical results display area;

the current result display area comprises a first area for displaying information of a currently tested sample and a second area for displaying information of a corresponding test item; the controller receives an instruction of a user to select a sample through a first area; in response to an instruction of a user selecting a sample received at the first area, the controller controls the second area to display information of a test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through the second area;

the abnormal sample display area comprises a third area and a fourth area, wherein the third area is used for displaying information of a sample of a current abnormal test result, and the fourth area is used for displaying information of a corresponding test item; the controller receives an instruction of a user to select a sample through a third area; in response to an instruction of a user selecting a sample received at the third area, the controller controls the fourth area to display information of the test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through the fourth area;

the historical result display area comprises a fifth area for displaying information of samples of historical tests and a sixth area for displaying information of corresponding test items; the controller receives an instruction of selecting a sample by a user through a fifth area; in response to an instruction of a user selecting a sample received at the fifth area, the controller controls the sixth area to display information of the test item corresponding to the sample; the controller receives an instruction of selecting a test item by a user through a sixth area;

in response to the user's instruction to select a sample and the user's instruction to select a test item, the controller determines the sample and its test item.

18. The sample analysis device of claim 17, wherein the result list display interface further comprises a reaction data acquisition control, and the controller receives a reaction data acquisition instruction through the reaction data acquisition control;

in response to a reaction data acquisition instruction, the controller acquires reaction data of the sample with respect to the test item according to the determined sample and the test item thereof.

19. The sample analysis device of claim 18, wherein the controller further generates the reaction data interface in response to the reaction data acquisition instruction.

20. The sample analysis device of claim 19, wherein in response to the reaction data acquisition instruction, the controller further controls a display to display the reaction data of the sample at the generated reaction data interface.

21. The sample analysis device of any of claims 16 to 20, wherein the reaction data interface further comprises a curve comparison control through which the controller receives a curve comparison instruction;

and responding to a curve comparison instruction, and controlling a display to display the reaction data of the sample and the reaction data of the comparison product on the reaction data interface by the controller.

22. The sample analysis device of claim 21, wherein in response to a curve comparison instruction, the controller further generates a first control for selecting a comparison product associated with the test item and a second control for selecting a test time for the comparison product at the reaction data interface; the controller receives an instruction of selecting a comparison product by a user through the first control and receives an instruction of selecting test time by the user through the second control;

in response to the instruction of the user selecting the contrast product and the instruction of the user selecting the test time, the controller determines the contrast product associated with the test item and the test time thereof.

23. The sample analysis device of claim 16, wherein the reaction data interface comprises a curvilinear display region and/or a numerical display region; the curve display area displays reaction data in a coordinate drawing point mode; the digital display area displays the reaction data in a digital list mode.

24. The sample analyzing apparatus according to claim 23, wherein the reaction data of the sample is different in color from the reaction data of the control in the curve display region.

25. The sample analysis device of claim 23, wherein the reaction data interface further comprises a curve adjustment control through which the controller receives a curve adjustment instruction; in response to the curve adjusting instruction, the controller adjusts the vertical coordinate proportion of the coordinates in the curve display area so as to enable the displayed different reaction data to be complete and clear; alternatively, the first and second electrodes may be,

the controller adjusts the vertical coordinate proportion of the coordinates in the curve display area in a self-adaptive mode, so that the displayed different reaction data are complete and clear.

26. The sample analyzing apparatus as claimed in claim 23, wherein the controller determines a parameter to be displayed in the reaction data in response to a parameter selection command for the reaction data, and controls the display to display the parameter to be displayed in the reaction data interface.

27. The apparatus of claim 26, wherein the controller captures a cursor position of the curve display area, and controls the display to display the coordinate value of the point in the vicinity of the point in the form of a numerical value when the cursor position is determined to be within a predetermined range of the point depicted in the curve display area.

28. The sample analysis device of claim 26 or 27, wherein the reaction data interface comprises a plurality of check boxes, each check box corresponding to a parameter in the reaction data; and any check box is checked to show that the controller receives a selection instruction of the corresponding parameter in the reaction data and determines that the parameter corresponding to the check box needs to be displayed in the reaction data.

29. The sample analysis device of claim 26, wherein the check boxes comprise a check box corresponding to a primary wavelength in the reaction data, a check box corresponding to a secondary wavelength in the reaction data, and a check box corresponding to the primary wavelength minus the secondary wavelength in the reaction data.

30. The sample analysis device of claim 16, wherein the contrast article comprises a standard and/or a quality control article.

31. A computer-readable storage medium, characterized by comprising a program executable by a processor to implement the method of any one of claims 1 to 15.

Images