CN115145431A

CN115145431A - Sample processing method, system, device, readable medium and sample analyzer

Info

Publication number: CN115145431A
Application number: CN202210796919.0A
Authority: CN
Inventors: 陈嘉惠; 周丹萍; 马德新
Original assignee: Zhongyuan Huiji Biotechnology Co Ltd
Current assignee: Zhongyuan Huiji Biotechnology Co Ltd
Priority date: 2022-07-06
Filing date: 2022-07-06
Publication date: 2022-10-04

Abstract

The invention provides a sample processing method, a system, equipment and a readable medium, which comprises the steps of firstly obtaining an instruction signal for recalculating one or more detection items of a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection item needing recalculation; then, matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result; and finally displaying the recalculation result. By the method, the target object can select the designated calibration parameters to recalculate the sample to be measured, and the recalculation results under different effective calibration parameters can be compared by selecting the designated calibration parameters; if the user selects a plurality of detection items, the method can also recalculate the plurality of detection items at the same time, thereby solving the defect problem in the prior art.

Description

Sample processing method, system, device, readable medium and sample analyzer

Technical Field

The present invention relates to the field of sample detection and analysis technologies, and in particular, to a sample processing method, a sample processing system, a computer device, a computer readable medium, and a sample analyzer.

Background

Sample analysis refers to a process of measuring chemical components or physiological characteristics of a sample to be measured, for example, immunoassay of a blood sample. However, in the prior art, when a sample is analyzed, designated calibration parameters cannot be selected for recalculation, recalculation results under different calculation calibration parameters cannot be compared, and a plurality of original calculation results cannot be recalculated at the same time.

Disclosure of Invention

In view of the above-mentioned shortcomings of the prior art, it is an object of the present invention to provide a sample processing method, system, computer device and computer readable medium for solving the problems in the prior art.

To achieve the above and other related objects, the present invention provides a sample processing method, comprising the steps of:

acquiring an instruction signal for recalculating one or more detection items on a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection item to be recalculated;

matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result;

and displaying the recalculation result.

Optionally, before matching the calculated scaling parameters associated with the current scaling mode according to the instruction signal, the method further comprises:

responding to the instruction signal, and judging whether the detection item of the sample to be detected, which needs to be recalculated, is audited;

giving up recalculation on the checked detection items, and outputting blank recalculation results; judging whether the non-checked detection items have response data or not;

giving up recalculation on the detection items without the reaction data, and outputting blank recalculation results; matching the calculation calibration parameters associated with the current calibration mode to the detection items of the given reaction data;

wherein the generation process of the reaction data comprises the following steps: and reacting a sample with a test reagent to obtain the reaction data, wherein the sample is a sample to be tested with unknown concentration.

responding to the command signal and determining whether the target object selected calibration parameter is a test agent associated calibration parameter available for the current calibration mode;

if so, taking the corresponding test reagent associated calibration parameter as a calculation calibration parameter associated with the current calibration mode; if not, displaying the calculation scaling parameter as null;

wherein if the current calibration mode is the batch change calibration mode, then identifying calibration parameters for which the calibration status associated with the reagent batch of test reagents is successful, expired, or deferred as test reagent associated calibration parameters for which the current calibration mode is available;

and if the current calibration mode is the bottle changing calibration mode, identifying the calibration parameter with the calibration state of success, expiration or delay associated with the batch bottle number of the test reagent as the test reagent associated calibration parameter available for the current calibration mode.

Optionally, when displaying the recalculation result, the method further comprises: displaying the detection items, result units, original calculation results, current calculation results, original calibration parameters and calculation calibration parameters which are recalculated at the current moment; or displaying the detection item, the result unit, the calculation calibration parameter, the number of the sample to be detected, the sample bar code, the serial number, the original calculation result, the original calibration parameter and the current calculation result which are recalculated at the current moment.

Optionally, before displaying the recalculation results, the method further comprises:

marking the recalculation results in a first type so that the recalculation results are different from the original calculation results;

displaying a recalculation result after the first class mark is completed;

and/or selecting an expired or delayed calibration parameter as a recalculation result of calculating the calibration parameter for the target object to carry out second-class marking;

and displaying the recalculation result after the second type of mark is completed.

The present invention also provides a sample processing system, comprising:

the signal receiving module is used for acquiring an instruction signal for recalculating one or more detection items on a sample to be detected, and the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection items needing recalculation;

the recalculation module is used for matching calculation calibration parameters related to the current calibration mode according to the instruction signal and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result;

and the display module is used for displaying the recalculation result.

Optionally, before matching the calculated scaling parameter associated with the current scaling mode according to the instruction signal, the recalculating module further comprises:

responding to the instruction signal, and judging whether the detection items of the sample to be detected, which need to be recalculated, are checked;

giving up recalculation on the detection items without the reaction data, and outputting blank recalculation results; matching the detection items of the reaction data with the calculation calibration parameters associated with the current calibration mode;

responding to the instruction signal, and determining whether the calibration parameter selected by the target object is a test reagent associated calibration parameter available in the current calibration mode;

if so, taking the corresponding test reagent associated calibration parameter as a calculation calibration parameter associated with the current calibration mode; if not, displaying the calculation calibration parameter as null;

and if the current calibration mode is the bottle changing calibration mode, determining the calibration parameters of which the calibration states associated with the batch bottle numbers of the test reagents are successful, expired or delayed as the calibration parameters associated with the test reagents available in the current calibration mode.

The present invention also provides a sample analyzer comprising a system as described in any of the above.

The present invention also provides a computer apparatus comprising:

a processor; and

a computer readable medium having stored thereon instructions which, when executed by the processor, cause the apparatus to perform the method as in any one of the above.

The invention also provides a computer readable medium having stored thereon instructions which are loaded by a processor and which perform the method as defined in any one of the above.

As described above, the present invention provides a sample processing method, system, device and readable medium, which have the following advantages: firstly, acquiring an instruction signal for recalculating one or more detection items on a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection items needing recalculation; then, matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result; and finally displaying the recalculation result. Therefore, by the method, the target object (such as a user) can select the designated calibration parameters to recalculate the sample to be measured, and the recalculation results under different effective calibration parameters can be compared by selecting the designated calibration parameters; in addition, if the user selects a plurality of detection items, the invention can also recalculate the plurality of detection items at the same time, thereby solving the defect problem in the prior art.

Drawings

FIG. 1 is a schematic flow chart of a sample processing method according to an embodiment;

FIG. 2 is a diagram illustrating a sample-by-sample view of a current computation provided by an embodiment;

FIG. 3 is a diagram illustrating a recalculation result of a single inspection item according to an embodiment;

FIG. 4 is a diagram illustrating an embodiment of selecting a calculation scaling parameter in a trade-off scaling mode;

FIG. 5 is a diagram illustrating a view of a current computation result by detection item, according to an embodiment;

FIG. 6 is a diagram illustrating a recalculation result of a plurality of inspection items according to an embodiment;

FIG. 7 is a diagram illustrating an embodiment of selecting a calculation calibration parameter in a bottle-changing calibration mode;

FIG. 8 is a diagram illustrating a hardware configuration of a sample processing system according to one embodiment;

fig. 9 is a schematic hardware structure diagram of a computer device according to an embodiment.

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the drawings only show the components related to the present invention rather than being drawn according to the number, shape and size of the components in actual implementation, and the type, amount and proportion of each component in actual implementation can be changed freely, and the layout of the components can be more complicated.

Calibration, namely calculating a fitted luminescence value of a calibrator according to the known concentration of the project calibrator and a main curve of a test reagent; then, adjusting the luminous value of the main curve of the test reagent according to the calculation method of each detection item by utilizing the actually measured luminous value and the fitted luminous value of the calibrator; and then 4PLC fitting is carried out on each calibration point luminous value of the adjusted main curve and each concentration point of the main curve to obtain project calibration parameters. For the immunological calibration, it can be used to calculate the final immunological item result, i.e. to calculate the immunological item concentration according to the known calibration parameter expression and the item reaction data (i.e. luminescence value) measured by the sample.

The batch changing calibration mode means that reagents participating in calibration test must be reagents of the same batch when the detection items are calibrated, but no requirement is made on the bottle number; and the obtained calibration parameters can be used for the sample and quality control test of the reagent of the same batch.

The bottle changing calibration mode refers to that when the detection items are calibrated, the reagents participating in the calibration test need to be the same batch of reagents with the same bottle number; and the obtained calibration parameters can be used for the sample and quality control test of the reagents in the same batch and the same bottle number.

The original calculation result (referred to as original result) refers to the result calculated based on the reagent used in the test or the original calibration parameter of the test reagent and the reaction data obtained by the test, i.e. the result obtained by the detection.

The current calculation result (referred to as a current result for short) refers to a result currently displayed by the detection item, which may be an original result or a processed result.

Recalculate the results (simply recalculated results), the specified test using the reagent or calibration parameter associated with the test reagent and the calculated results of the current reaction data.

The original calibration parameters refer to default calibration parameters corresponding to the test reagent or the test reagent when testing the item.

Calculating calibration parameters, which refer to available calibration parameters associated with the test use reagent or the test reagent according to the current calibration mode; including default scaling parameters and non-default scaling parameters.

Default calibration parameters refer to that a test reagent is calibrated for multiple times to generate a plurality of available reagent-associated calibration parameters, wherein one of the calibration parameters is set as a calibration parameter for result calculation, namely the default calibration parameter; the default scaling parameters are typically the scaling parameters for which the newly generated scaling state is successful.

The non-default scaling parameters refer to other scaling parameters except for the default scaling parameters.

The reagent-associated calibration parameters include calibration parameters obtained by calibrating the reagent itself, and calibration parameters obtained by calibrating the reagent with the same batch number as the reagent. Wherein the main curve is a specific immune item reagent-associated calibration parameter.

Referring to fig. 1, the present invention provides a sample processing method, including the steps of:

s100, acquiring an instruction signal for recalculating one or more detection items of a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection item to be recalculated. As an example, as shown in fig. 2 to 4, on a display interface for viewing the current calculation result by pressing a sample, a target object may select a sample number 0001 and a detection item TT3, and when a "recalculation" button is clicked after the detection item TT3 is checked, the checked detection item, result unit, original result, current result, calculation scaling parameter and recalculation result (default is null) are displayed in a pop-up manner, and when the target object is further pulled down to select a specified calculation scaling parameter, the "recalculation" button is clicked, and at this time, an instruction signal for recalculating the detection item TT3 for the sample 0001 to be measured is generated according to the click of the "recalculation" button by the target object. As another example, as shown in fig. 5 to 7, on the display interface for viewing the current calculation result according to the detection item, the target object may select the item TT3, the test list displays all the test results of the TT3, the test results of the sample numbers 202201010001-202201010004 are selected, meanwhile, the "recalculation" button is clicked, at this time, a popup window displays that the selected detection item is TT3, the result unit is mmol/L, the calculation calibration parameter is null, the list displays the sample barcodes, the serial numbers, the original results, the original calibration parameters, the current result, and the recalculation result (default is null), when the target object is pulled down again to select the designated calculation calibration parameter, and the "recalculation" button is clicked, at this time, according to the click on the "recalculation" button of the target object, an instruction signal for recalculating the detection item TT3 on the sample numbers 202201010001-202201010004 to be detected is generated. The target object in this embodiment is a person, which may be, for example, a user, an experimenter, or the like, and the specific identity of the target object is not limited in this embodiment.

S200, matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result. In this embodiment, when a certain detection item includes a plurality of sub-items, after at least one of the sub-items is recalculated, the corresponding detection item is also recalculated; if the calculation of the corresponding detection item fails after the sub-items of the detection item are modified, the recalculation result of the sub-item cannot be saved. In this embodiment, if the recalculation of the detection item fails, for example, if there is no recalculation result, a reason for the recalculation failure is prompted. As an example, the reason for prompting a recalculation failure may be: RRNE; namely, the specific result value cannot be calculated after the sample result luminous value exceeds the maximum value of the luminous value of the calibrator, and the recalculation is considered to fail.

And S300, displaying the recalculation result. As an example, as shown in fig. 3, when displaying the recalculation result, the present embodiment may further display the detection item, the result unit, the original result, the current result, the original scaling parameter, and the calculation scaling parameter, which are recalculated at the current time. As another example, as shown in fig. 6, when displaying the recalculation result, the present embodiment may further display the detection item, the result unit, the calculation calibration parameter, the number of the sample to be measured, the sample barcode, the serial number, the original result, the original calibration parameter, and the current result, which are recalculated at the current time.

Therefore, by the embodiment, the target object (for example, a user) can select the designated calibration parameters to recalculate the sample to be measured, and by selecting the designated calibration parameters, recalculation results under different effective calibration parameters can be compared; in addition, if the user selects a plurality of detection items, the embodiment can also recalculate the plurality of detection items at the same time, thereby solving the defect problem in the prior art.

According to the above description, in an exemplary embodiment, step S200 further includes, before matching the calculated scaling parameter associated with the current scaling mode according to the instruction signal: responding to the instruction signal, and judging whether the detection item of the sample to be detected, which needs to be recalculated, is audited; giving up recalculation on the checked detection items, and outputting blank recalculation results; judging whether the non-checked detection items have response data or not; giving up recalculation on the detection items without the reaction data, and outputting blank recalculation results; and matching the calculation calibration parameters associated with the current calibration mode to the detection items of the given reaction data. Wherein the generation process of the reaction data comprises the following steps: and reacting a sample with a test reagent to obtain the reaction data, wherein the sample is a sample to be tested with unknown concentration. Therefore, in this embodiment, the first type of basic condition may be determined before the recalculation of the sample to be tested. Namely, whether the detection items of the sample to be detected, which need to be recalculated, are the checked detection items and whether the detection items are the detection items with the response data. Items equivalent to the checked samples cannot be modified and cannot be recalculated; regarding the conventional items without reaction data and the conventional items which cannot be tested as non-reaction data, recalculation cannot be carried out; the recalculation cannot be performed for the detection items of the non-reaction data.

According to the above description, in an exemplary embodiment, step S200 further includes, before matching the calculated scaling parameter associated with the current scaling mode according to the instruction signal: responding to the command signal and determining whether the target object selected calibration parameter is a test agent associated calibration parameter available for the current calibration mode; if so, taking the corresponding test reagent associated calibration parameter as a calculation calibration parameter associated with the current calibration mode; and if not, displaying the calculation scaling parameter as null. Wherein if the current calibration mode is the batch change calibration mode, then the calibration parameter for which the calibration status associated with the reagent batch of test reagent is successful, expired, or deferred is identified as the test reagent associated calibration parameter for which the current calibration mode is available. And if the current calibration mode is the bottle changing calibration mode, identifying the calibration parameter with the calibration state of success, expiration or delay associated with the batch bottle number of the test reagent as the test reagent associated calibration parameter available for the current calibration mode. Therefore, in this embodiment, the second type of basic condition may be determined before the recalculation of the sample to be tested is performed. That is, before recalculation, it is determined whether the calibration parameters selected by the target object have available reagent-associated calibration parameters. The calibration status associated with a reagent lot of test reagent in the lot change calibration mode is equivalent to successful, expired, deferred calibration parameters and master curves, which are available for recalculation. And in the bottle changing calibration mode, calibration parameters of which the calibration state associated with the batch bottle number of the test reagent is success, expiration and delay are available for recalculation. If no reagent-associated calibration parameters are available, no recalculation is possible. Wherein, when the calibration mode is switched from a lot change calibration to a vial change calibration, no reagent-associated calibration parameters are available for the test reagent.

In accordance with the above, in an exemplary embodiment, before displaying the recalculation results, the method further comprises: marking the recalculation result with a first type so that the recalculation result is different from the original calculation result; and displaying the recalculation result after the first type mark is completed. And/or selecting an expired or delayed calibration parameter as a recalculation result of calculating the calibration parameter for the target object to carry out second-class marking; and then displaying the recalculation result after the second type of mark is completed. As shown in fig. 3 or fig. 6, the present embodiment may mark the original result and the recalculated result with different gray levels. In the embodiment, the original result and the recalculation result are marked, so that the original result and the recalculation result can be distinguished obviously on the display interface.

According to the above description, in one embodiment, a sample processing method is provided, including:

and 11, generating a recalculated instruction signal according to the operation of the user. Specifically, pressing a sample viewing interface, selecting and checking items with results in a test list in a single mode, clicking a 'recalculation' button, displaying and checking items, result units, original results, current results, calculation calibration parameters and recalculation results (default is null), pulling down and selecting specified calculation calibration parameters, clicking the 'recalculation' button, and generating an instruction signal for recalculation. In addition, when the recalculation results show the results calculated using the selected calculation scaling parameters, the recalculation is completed by clicking the "save" button.

And step 12, calculating a calibration parameter selection popup.

121 Display the calibration parameters and master curve (only in the reprime calibration mode, labeled "M") associated with the use of the reagent that corresponds to the calibration status of success, expiration, delay for the current calibration mode.

122 In the batch-changing calibration mode, the calibration parameters are calculated to display the calibration parameters and the main curve associated with the reagent batch, and the current default calibration parameters of the reagent batch are selected by default; and under the bottle changing calibration mode, calculating calibration parameters, displaying the calibration parameters related to the bottle number of the reagent batch, and selecting the current default calibration parameters of the bottle number of the reagent batch by default.

123 When no reagent-associated calibration parameters are used, the calculation calibration parameters are displayed empty and cannot be recalculated, and the recalculation button is grayed out to indicate "no available calibration parameters".

Step 13, clicking a 'recalculation' button, and if the calculation fails, prompting the reason of the calculation failure in the recalculation result as follows: and (3) RRNE.

And step 14, storing the recalculated result, covering the current result on the result display interface, and still viewing the original result on the pop-up window.

Step 15, displaying the recalculated test result in the prompt bar! "; the prompt bar prompts "+" using the test result of the overdue or deferred calibration parameter recalculation.

Step 16, after recalculating the sub-items of the calculation item, recalculating the calculation item, the prompt field also displaying "! "; if the calculation of the calculation item fails after the sub-item of the calculation item is modified, click the "save" button, and pop the window to prompt that the recalculation of the sub-item results in the failure of the calculation item results, which cannot be saved! ", the sub-item recalculation failed to save.

And step 17, when recalculation is not carried out or calculation fails, setting grey by a 'save' button, and prompting 'no result storable'.

Specifically, as shown in fig. 2 to 4, for a sample with a sample number of 0001, application 2022/01/01 08; item TT3 can be checked, the "recalculate" button is clicked, the popup shows that the item is TT3, the result unit is mmol/L, the original result is 28.56, the current result is 25.00, the original scaling parameter is 2021/12/30 10.

In the test in the batch change calibration mode, the test uses reagent lot number = original calibration parameter lot number, and the vial number may be different.

The calculated calibration parameter popup is selected by clicking, because the current mode is the batch changing calibration mode, the calibration parameter and the main curve generated by the reagent batch 20211215 are displayed in the popup, the main curve can be selected, and the calibration parameter with the batch number 20211215 bottle number 1, the calibration parameter with the batch number 20211215 bottle number 2 and the calibration parameter with the batch number 20211215 bottle number 3 can also be selected.

Selecting 2022/01/01 10; selecting 2022/01/01 09; selecting 2022/01/01 10. And after the recalculation results are compared for multiple times, selecting the recalculation result of the most appropriate calculation calibration parameter for storage.

In accordance with the above, in another embodiment, there is provided a sample processing method comprising the steps of:

step 21, generating a recalculated instruction signal according to the operation of the user. According to an item viewing interface, selecting a conventional item, checking a test result of a result in a test list, clicking a 'recalculation' button, displaying a check item, a result unit and a calculation calibration parameter on a popup window, displaying a sample number, a sample bar code, a serial number, an original result, an original calibration parameter, a current result and a recalculation result (null) corresponding to a result needing batch recalculation on the list (arranged according to the ascending order of the sample numbers), pulling down to select the specified calculation calibration parameter, and clicking the 'recalculation' button to generate an instruction signal for recalculation. In addition, the recalculation result associated with the parameter displays the result obtained by calculation by using the selected calculation calibration parameter, all test results can be recalculated by switching the calculation calibration parameter, the recalculation result which is not empty can be saved by clicking a 'save' button, and the recalculation popup window can be closed by clicking to close after the recalculation is saved.

And step 22, calculating a calibration parameter selection popup.

221 Display the calibration parameters and master curve (only in batch-change calibration mode, labeled "M") associated with the use of reagents for check results, with the calibration status of success, expiration, delay, consistent with the current calibration mode.

222 Calibration parameters can be selected only singly, under the batch changing calibration mode, if the test results of the same reagent batch are selected for recalculation, the calibration parameters are calculated and the calibration parameters and the main curve related to the reagent batch are displayed, the current default calibration parameters of the reagent batch are selected by default, and all results are recalculated after a parameter is selected and a 'recalculation' button is clicked; if the test results of different batches of reagents are selected, the calibration parameters are calculated, the calibration parameters and the main curves which are associated with different reagent batches are specified to be displayed, any calibration parameter is not selected by default, a parameter is selected, a 'recalculation' button is clicked, only the result of the reagent batch associated with the parameter is recalculated, and the rest of the results are grayed and displayed to be maintained as the original result. Under the bottle changing calibration mode, if the test result of the same reagent batch bottle number is selected for recalculation, the calibration parameters are calculated and the calibration parameters related to the reagent batch bottle number are displayed, the current default calibration parameters of the reagent batch bottle number are selected by default, and all results are recalculated after a parameter is selected and a recalculation button is clicked; if the test results of different batches of bottle numbers are selected, the calibration parameters are calculated and displayed to designate the calibration parameters related to the bottle numbers of different reagent batches, any calibration parameter is not selected by default, a parameter is selected and a 'recalculation' button is clicked, only the result of the bottle number of the reagent batch related to the parameter is recalculated, and the rest of the results are grayed and displayed to maintain the original shape.

223 When no reagent related calibration parameter exists in the used reagent batch bottle number, the calculation calibration parameter is displayed to be empty, recalculation cannot be carried out, and the recalculation button is grayed out to prompt that no available calibration parameter exists.

And step 23, storing the recalculated result, covering the current result on the result display interface, and still viewing the original result on the pop-up window.

And 24, clicking a recalculation button, and if the calculation fails, prompting the reason of the calculation failure in the recalculation result as follows: and (3) RRNE.

Step 25, displaying the recalculated test result in the prompt bar! "; the prompt bar prompts "+" using the test results of the expired or deferred calibration parameter recalculation.

Step 26, after recalculating the sub-items of the calculation item, recalculating the calculation item, the hint column also displaying "! "; if the calculation of the calculation item fails after the sub-item of the calculation item is modified, click the "save" button, and pop the window to prompt that the recalculation of the sub-item results in the failure of the calculation item results, which cannot be saved! ", the sub-item recalculation failed to save.

And 27, when recalculation is not carried out or calculation fails, setting grey on a save button, and prompting that no result can be saved when grey is set.

Specifically, as shown in fig. 5 to 7, the item TT3 is selected, the test list displays all test results of the TT3, the test results of sample numbers 202201010001-202201010004 are selected, the "recalculation" button is clicked, the popup window displays the item TT3, the result unit is mmol/L, the calculation calibration parameter (is empty), and the list displays the sample barcodes, the serial numbers, the original results, the original calibration parameters, the current results, and the recalculation results of the sample numbers 202201010001-202201010004 (default is empty).

The test was conducted in a vial change calibration mode using the reagent lot number vial = the lot number vial of the original calibration parameters.

The calculation calibration parameter popup is selected by clicking, and because the current mode is the bottle change calibration mode, the popup displays the calibration parameter generated by the reagent batch number 20211201 with the bottle number 1 and the calibration parameter generated by the reagent batch number 20211201 with the bottle number 2, the calibration parameter of the batch number 20211201 with the bottle number 1 can be selected by using the result of the reagent test of the reagent batch number 20211201 with the bottle number 1, and the calibration parameter of the batch number 20211201 with the bottle number 2 can be selected by using the result of the reagent test of the reagent batch number 20211201 with the bottle number 2.

Selecting 2022/01/01 08; selecting 2022/01/01 08; and so on.

And after the recalculation results are compared for multiple times, the recalculation result of the most appropriate calculation calibration parameter is selected for storage.

In summary, the present invention provides a sample processing method, which includes obtaining an instruction signal for recalculating one or more detection items for a sample to be detected, where the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and a detection item to be recalculated; then, matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result; and finally displaying the recalculation result. Therefore, by the method, a target object (such as a user) can select the designated calibration parameters to recalculate the sample to be measured, and the recalculation results under different effective calibration parameters can be compared by selecting the designated calibration parameters; in addition, if the user selects a plurality of detection items, the method can also recalculate the plurality of detection items at the same time, thereby solving the defect problem in the prior art.

As shown in fig. 8, the present invention also provides a sample processing system, comprising:

and the signal receiving module M10 is used for acquiring an instruction signal for recalculating one or more detection items on the sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after the target object selects the calibration parameters and the detection items needing recalculation. As an example, as shown in fig. 2 to 4, on a display interface for checking a current calculation result by pressing a sample, a target object may select a sample number 0001 and a detection item TT3, and when a "recalculation" button is clicked after the detection item TT3 is checked, a pop-up window may display the checked detection item, result unit, original result, current result, calculation scaling parameter, and recalculation result (default is null), and when the target object is further pulled down to select a specified calculation scaling parameter, the "recalculation" button is clicked, and then an instruction signal for recalculating the detection item TT3 for the sample 0001 to be measured is generated according to the click of the "recalculation" button by the target object. As another example, as shown in fig. 5 to 7, on the display interface for viewing the current calculation result according to the detection item, the target object may select the item TT3, the test list displays all the test results of the TT3, the test results of the sample numbers 202201010001-202201010004 are selected, meanwhile, the "recalculation" button is clicked, at this time, a popup window displays that the selected detection item is TT3, the result unit is mmol/L, the calculation calibration parameter is null, the list displays the sample barcodes, the serial numbers, the original results, the original calibration parameters, the current result, and the recalculation result (default is null), when the target object is pulled down again to select the designated calculation calibration parameter, and the "recalculation" button is clicked, at this time, according to the click on the "recalculation" button of the target object, an instruction signal for recalculating the detection item TT3 on the sample numbers 202201010001-202201010004 to be detected is generated. The target object in this embodiment is a person, which may be, for example, a user, an experimenter, or the like, and the specific identity of the target object is not limited in this embodiment.

And the recalculation module M20 is configured to match the calculation calibration parameter associated with the current calibration mode according to the instruction signal, and perform recalculation on one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameter to obtain a recalculation result. In this embodiment, when a certain detection item includes a plurality of sub-items, after recalculation is performed on at least one of the sub-items, recalculation is performed on the corresponding detection item; if the calculation of the corresponding detection item fails after the sub-items of the detection item are modified, the recalculation result of the sub-item cannot be saved. In this embodiment, if the recalculation of the detection item fails, for example, if there is no recalculation result, the reason for the recalculation failure is prompted. As an example, the reason for prompting a recalculation failure may be: an RRNE; that is, the specific result value cannot be calculated after the light-emitting value of the sample result exceeds the maximum value of the light-emitting value of the calibrator, and the recalculation is considered to fail.

And a display module M30, configured to display the recalculation result. As an example, as shown in fig. 3, when displaying the recalculation result, the present embodiment may further display the detection item, the result unit, the original result, the current result, the original scaling parameter, and the calculation scaling parameter, which are recalculated at the current time. As another example, as shown in fig. 6, when displaying the recalculation result, the present embodiment may further display the detection item, the result unit, the calculation calibration parameter, the number of the sample to be measured, the sample barcode, the serial number, the original result, the original calibration parameter, and the current result, which are recalculated at the current time.

According to the above description, in an exemplary embodiment, before matching the calculated scaling parameter associated with the current scaling mode according to the instruction signal, the recalculation module M20 further includes: responding to the instruction signal, and judging whether the detection item of the sample to be detected, which needs to be recalculated, is audited; giving up recalculation on the checked detection items, and outputting blank recalculation results; judging whether the non-checked detection items have response data or not; giving up recalculation on the detection items without the reaction data, and outputting blank recalculation results; and matching the calculation calibration parameters associated with the current calibration mode to the detection items of the reaction data. Wherein the generation process of the reaction data comprises the following steps: and reacting a sample with a test reagent to obtain the reaction data, wherein the sample is a sample to be tested with unknown concentration. Therefore, in this embodiment, the first type of basic condition may be determined before the recalculation of the sample to be tested. Namely, whether the detection items of the sample to be detected, which need to be recalculated, are the checked detection items and whether the detection items are the detection items with the response data. Items equivalent to the checked samples cannot be modified and cannot be recalculated; regarding the conventional items without reaction data and the conventional items which cannot be tested as non-reaction data, recalculation cannot be carried out; the recalculation cannot be performed for the detection items of the non-reaction data.

According to the above description, in an exemplary embodiment, before matching the calculated scaling parameter associated with the current scaling mode according to the instruction signal, the recalculation module M20 further includes: responding to the command signal and determining whether the target object selected calibration parameter is a test agent associated calibration parameter available for the current calibration mode; if so, taking the corresponding test reagent associated calibration parameter as a calculation calibration parameter associated with the current calibration mode; and if not, displaying the calculation scaling parameter as null. Wherein if the current calibration mode is the batch change calibration mode, calibration parameters for which the calibration status associated with the reagent batch of test reagents is successful, expired, or deferred are identified as test reagent associated calibration parameters for which the current calibration mode is available. And if the current calibration mode is the bottle changing calibration mode, identifying the calibration parameter with the calibration state of success, expiration or delay associated with the batch bottle number of the test reagent as the test reagent associated calibration parameter available for the current calibration mode. Therefore, in this embodiment, the second type of basic condition may be determined before the recalculation of the sample to be tested is performed. That is, before recalculation, it is determined whether the target object selected calibration parameter has an available reagent-associated calibration parameter. Calibration parameters and master curves corresponding to successful, expired, delayed calibration status associated with a reagent lot of test reagent in the batch change calibration mode are available for recalculation. And in the bottle changing calibration mode, the calibration state associated with the batch bottle number of the test reagent is a successful calibration parameter, an expired calibration parameter and a delayed calibration parameter, and the calibration parameters can be used for recalculation. If no reagent-associated calibration parameters are available, no recalculation can be performed. Wherein when the calibration mode is switched from a lot change calibration to a vial change calibration, no reagent-associated calibration parameters are available for the test reagent.

According to the above description, in an exemplary embodiment, before displaying the recalculation result, the display module M30 further includes: marking the recalculation results in a first type so that the recalculation results are different from the original calculation results; and displaying the recalculation result after the first type mark is completed. And/or selecting an expired or delayed calibration parameter as a recalculation result of calculating the calibration parameter for the target object to carry out second-class marking; and displaying the recalculation result after the second type mark is completed. As shown in fig. 3 or fig. 6, the present embodiment may mark the original result and the recalculated result with different gray levels. In the embodiment, the original result and the recalculation result are marked, so that the original result and the recalculation result can be distinguished obviously on the display interface.

It should be noted that the sample processing system provided in the foregoing embodiment and the sample processing method provided in the foregoing embodiment belong to the same concept, and specific ways of performing operations by the respective modules and units have been described in detail in the method embodiment, and are not described herein again. In practical applications, the sample processing system provided in the above embodiment may distribute the above functions by different functional modules according to needs, that is, the internal structure of the system is divided into different functional modules to complete all or part of the above described functions, which is not limited herein. For example, in one embodiment, a sample processing system is provided for performing a sample detection procedure as in fig. 2-4. In yet another embodiment, a sample processing system is provided for performing the sample testing procedure of fig. 5-7.

In summary, the present invention provides a sample processing system, which first obtains an instruction signal for recalculating one or more detection items for a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and a detection item to be recalculated; then, matching calculation calibration parameters associated with the current calibration mode according to the instruction signal, and recalculating one or more detection items of the sample to be detected based on the current calibration mode and the calculation calibration parameters to obtain a recalculation result; and finally displaying the recalculation result. Therefore, by the system, a target object (such as a user) can select the designated calibration parameters to recalculate the sample to be measured, and the recalculation results under different effective calibration parameters can be compared by selecting the designated calibration parameters; in addition, if the user selects a plurality of detection items, the system can also recalculate the plurality of detection items at the same time, thereby solving the defect problem in the prior art.

The present invention also provides a sample analyzer comprising a sample processing system as described in any of the above. It should be noted that, in practical applications, the sample analyzer provided in the foregoing embodiment may allocate functions in the sample analysis system to different functional modules according to needs, that is, the internal structure of the system is divided into different functional modules to complete all or part of the functions described above, which is not limited herein.

An embodiment of the present application further provides a computer device, where the computer device may include: one or more processors; and one or more machine readable media having instructions stored thereon that, when executed by the one or more processors, cause the device to perform the method of fig. 1. Fig. 9 shows a schematic structural diagram of a computer device 1000. Referring to fig. 9, a computer apparatus 1000 includes: a processor 1010, a memory 1020, a power source 1030, a display unit 1040, an input unit 1060.

The processor 1010 is a control center of the computer apparatus 1000, connects the respective components using various interfaces and lines, and performs various functions of the computer apparatus 1000 by running or executing software programs and/or data stored in the memory 1020, thereby performing overall monitoring of the computer apparatus 1000. In the embodiment of the present application, the processor 1010 executes the method described in fig. 1 when calling the computer program stored in the memory 1020. Alternatively, processor 1010 may include one or more processing units; preferably, the processor 1010 may integrate an application processor, which primarily handles operating systems, user interfaces, applications, etc., and a modem processor, which primarily handles wireless communications. In some embodiments, the processor, memory, and/or memory may be implemented on a single chip, or in some embodiments, they may be implemented separately on separate chips.

The memory 1020 may mainly include a program storage area and a data storage area, wherein the program storage area may store an operating system, various applications, and the like; the storage data area may store data created according to use of the computer device 1000, and the like. Further, the memory 1020 may include high speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other volatile solid state storage device.

The computer device 1000 also includes a power supply 1030 (e.g., a battery) that provides power to the various components, which may be logically coupled to the processor 1010 through a power management system that may be used to manage charging, discharging, and power consumption.

The display unit 1040 may be used to display information input by a user or information provided to the user, and various menus of the computer device 1000, and is mainly used to display a display interface of each application in the computer device 1000, and objects such as texts and pictures displayed in the display interface in the embodiment of the present invention. The display unit 1040 may include a display panel 1050. The Display panel 1050 may be configured in the form of a Liquid Crystal Display (LCD), an Organic Light-Emitting Diode (OLED), or the like.

The input unit 1060 may be used to receive information such as numbers or characters input by a user. The input unit 1060 may include a touch panel 1070 and other input devices 1080. The touch panel 1070, also referred to as a touch screen, may collect touch operations by a user (e.g., operations by a user on the touch panel 1070 or near the touch panel 1070 using a finger, a stylus, or any other suitable object or attachment).

Specifically, the touch panel 1070 can detect a touch operation of a user, detect signals generated by the touch operation, convert the signals into touch point coordinates, transmit the touch point coordinates to the processor 1010, and receive and execute a command transmitted from the processor 1010. In addition, the touch panel 1070 may be implemented using various types of resistive, capacitive, infrared, and surface acoustic wave. Other input devices 1080 may include, but are not limited to, one or more of a physical keyboard, function keys (such as volume control keys, power on/off keys, etc.), a trackball, a mouse, a joystick, and the like.

Of course, the touch panel 1070 may cover the display panel 1050, and when the touch panel 1070 detects a touch operation thereon or nearby, the touch operation is transmitted to the processor 1010 to determine the type of the touch event, and then the processor 1010 provides a corresponding visual output on the display panel 1050 according to the type of the touch event. Although in fig. 9 the touch panel 1070 and the display panel 1050 are implemented as two separate components to implement the input and output functions of the computer device 1000, in some embodiments the touch panel 1070 and the display panel 1050 may be integrated to implement the input and output functions of the computer device 1000.

The computer device 1000 may also include one or more sensors, such as pressure sensors, gravitational acceleration sensors, proximity light sensors, and the like. Of course, the computer device 1000 may also include other components such as a camera, as desired for a particular application.

Embodiments of the present application further provide a computer-readable storage medium, where instructions are stored, and when executed by one or more processors, enable the above-mentioned device to perform the method described in this application and shown in fig. 1.

Those skilled in the art will appreciate that fig. 9 is merely exemplary of a computer device and is not intended to limit the device, which may include more or fewer components than illustrated, or some of the components may be combined, or different components. For convenience of description, the above parts are separately described as modules (or units) according to functional division. Of course, the functionality of the various modules (or units) may be implemented in the same one or more pieces of software or hardware when implementing the present application.

Those skilled in the art will appreciate that the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, etc.) having computer-usable program code embodied therein. The present application has been described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the application, and it is understood that each flowchart illustration and/or block diagram block and combination of flowchart illustrations and/or block diagrams block and computer program instructions may be implemented by computer program instructions. These computer program instructions may be applied to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks. 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 instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks. These 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 in the flowchart flow or flows and/or block diagram block or blocks.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Those skilled in the art can modify or change the above-described embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims

1. A method of sample processing, the method comprising the steps of:

acquiring an instruction signal for recalculating one or more detection items of a sample to be detected, wherein the instruction signal is obtained by triggering a preset control button after a target object selects a calibration parameter and the detection item to be recalculated;

and displaying the recalculation result.

2. The sample processing method of claim 1, wherein before matching the calculated scaling parameters associated with the current scaling mode based on the instruction signal, the method further comprises:

3. The sample processing method according to claim 1 or 2, wherein before matching the calculated scaling parameters associated with the current scaling mode based on the instruction signal, the method further comprises:

4. The sample processing method of claim 1, wherein in displaying the recalculation results, the method further comprises: displaying the detection items, result units, original calculation results, current calculation results, original calibration parameters and calculation calibration parameters which are recalculated at the current moment; or displaying the detection item, the result unit, the calculation calibration parameter, the number of the sample to be detected, the sample bar code, the serial number, the original calculation result, the original calibration parameter and the current calculation result which are recalculated at the current moment.

5. The sample processing method of claim 1 or 4, wherein prior to displaying the recalculation results, the method further comprises:

marking the recalculation result with a first type so that the recalculation result is different from the original calculation result;

displaying a recalculation result after the first class mark is completed;

and/or selecting an overdue or postponed calibration parameter as a recalculation result of the calculation calibration parameter for the target object to carry out second-class marking;

6. A sample processing system, comprising:

and the display module is used for displaying the recalculation result.

7. The sample processing system of claim 6, wherein the recalculation module further comprises, before matching the calculated scaling parameters associated with the current scaling mode based on the instruction signal:

8. The sample processing system of claim 6 or 7, wherein the recalculation module further comprises, before matching the calculated scaling parameters associated with the current scaling mode based on the instruction signal:

9. A sample analyser, characterised in that it comprises a system according to any one of claims 6 to 8.

10. A computer device, comprising:

a processor; and the combination of (a) and (b),

a computer readable medium having stored thereon instructions that, when executed by the processor, cause the apparatus to perform the method of any of claims 1 to 5.

11. A computer-readable medium having stored thereon instructions which are loaded by a processor and which perform the method of any one of claims 1 to 5.