CN114155930A - Report issuing method, device, equipment and storage medium - Google Patents

Abstract

The application provides a report issuing method, a report issuing device, report issuing equipment and a storage medium, wherein the method comprises the following steps: acquiring an experiment plate number, wherein the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to a target detection pore plate; inquiring a plurality of sample information corresponding to the experiment board number, wherein the plurality of sample information are respectively the sample information of the plurality of samples; determining sample release information corresponding to the plurality of samples according to the plurality of sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result; and under the condition that a report issuing instruction is acquired, responding to the report issuing instruction, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises sample issuing information corresponding to one sample. The technical scheme can release reports in batches, and the report release efficiency is improved.

Description

Report issuing method, device, equipment and storage medium

Technical Field

The present application relates to the field of sample detection, and in particular, to a report issuing method, apparatus, device, and storage medium.

Background

Novel coronavirus pneumonia (corona virus disease 2019, COVID-19) is a globally concerned disease in recent two years, and detection of the novel coronavirus is an effective means for finding novel coronavirus infection as soon as possible. After the epidemic situation happens, the epidemic situation can be restrained in a small range by carrying out comprehensive nucleic acid detection work, and the epidemic situation is prevented from spreading.

When laboratory detection personnel finish the nucleic acid detection work on a sample, the nucleic acid detection results need to be recorded one by one according to the bar codes, and then nucleic acid detection reports corresponding to the nucleic acid detection results are issued one by one. During comprehensive nucleic acid detection, the number of samples is often huge, and the method of inputting nucleic acid detection results one by one and issuing nucleic acid detection reports is low in efficiency and cannot meet the requirement of rapidly issuing reports.

Disclosure of Invention

The application provides a report issuing method, a report issuing device, report issuing equipment and a storage medium, and aims to solve the technical problem of low efficiency caused by a mode of recording nucleic acid detection results and issuing nucleic acid detection reports one by one.

In a first aspect, a report issuing method is provided, including:

acquiring an experiment plate number, wherein the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to a target detection pore plate;

inquiring a plurality of sample information corresponding to the experiment board number, wherein the plurality of sample information are respectively the sample information of the plurality of samples;

determining sample release information corresponding to the plurality of samples according to the plurality of sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result;

and under the condition that a report issuing instruction is acquired, responding to the report issuing instruction, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises sample issuing information corresponding to one sample.

In the technical scheme, sample information of a plurality of samples corresponding to one detection pore plate is inquired according to the number of the experiment plate, sample issuing information of the plurality of samples is determined according to the sample information of the plurality of samples, the sample issuing information comprises user information and sample detection results, and then under the condition that a report issuing instruction is obtained, a plurality of sample detection reports corresponding to one detection pore plate are generated and issued according to the sample issuing information of the plurality of samples. Batch generation and release of sample detection reports of a plurality of samples corresponding to one detection pore plate are realized based on one experiment plate number, and the report release efficiency can be improved; in addition, because the sample release information of a plurality of samples of one detection pore plate is directly determined according to one experimental plate number, the detection personnel can conveniently check and mark the sample detection results detected in the same batch, and great convenience is brought to the checking work of sample detection.

With reference to the first aspect, in a possible implementation manner, the determining, according to the plurality of sample information, sample distribution information corresponding to each of the plurality of samples includes: generating a sample detection result for each sample information in the plurality of sample information according to a preset result dictionary, and acquiring user information corresponding to each sample information in the plurality of sample information; and determining sample release information corresponding to the plurality of samples according to the user information corresponding to the sample information and the sample detection result of the sample information. By generating the sample detection result for each sample information according to the preset result dictionary, batch entry of the sample detection results is realized, users do not need to enter one by one, and the entry efficiency of the sample detection results can be improved.

With reference to the first aspect, in a possible implementation manner, the sample issuing information further includes a sample type, a reagent protocol, a reagent batch number, and/or an experiment number; before generating and publishing a plurality of detection reports corresponding to the target detection pore plate according to the sample publishing information corresponding to the plurality of samples, the method further includes: modifying first sample issuing information according to a content modification instruction under the condition that the content modification instruction aiming at the first sample issuing information is obtained, wherein the content modification instruction is used for indicating that at least one item of a issuing language type of the first sample issuing information, a sample detection result corresponding to the first sample issuing information, a sample type corresponding to the first sample issuing information, a reagent scheme corresponding to the first sample issuing information, a reagent batch number corresponding to the first sample issuing information or an experiment number corresponding to the first sample issuing information is modified. By providing the content correction function, the user can modify the sample release information, thereby being capable of meeting different requirements.

With reference to the first aspect, in a possible implementation manner, after querying the plurality of sample information corresponding to the assay plate number, the method further includes: and displaying a sample information detailed interface, wherein the sample information detailed interface is used for displaying the plurality of sample information, and the plurality of sample information are arranged in the sample information detailed interface according to the arrangement mode of the plurality of samples on the target detection pore plate. After the sample information of a plurality of samples corresponding to one detection pore plate is inquired, the interface is requested in detail by displaying the sample information, and the sample information can be intuitively corresponding to the samples on the detection pore plate because the sample information is arranged according to the arrangement mode of the samples on the detection pore plate, so that a user can conveniently mark and track the samples.

With reference to the first aspect, in a possible implementation manner, the generating and publishing a plurality of sample detection reports corresponding to the target detection well plate according to sample publishing information corresponding to each of the plurality of samples includes: when a review instruction for a target sample in the plurality of samples is acquired, generating and issuing a sample detection report corresponding to other samples except the target sample in the plurality of samples according to sample issuing information corresponding to each of the plurality of samples, wherein the review instruction is used for instructing to review a sample detection result corresponding to the target sample.

With reference to the first aspect, in a possible implementation manner, after determining, according to the plurality of sample information, sample release information corresponding to each of the plurality of samples, the method further includes: and under the condition that a report preview instruction for second sample issuing information is acquired, generating a sample detection report corresponding to the second sample issuing information and performing preview display. Through the report previewing function, a user can conveniently check and verify the report before the report is issued.

In a second aspect, a report issuing apparatus is provided, including:

the acquisition module is used for acquiring an experiment plate number, and the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to the target detection pore plate;

the query module is used for querying a plurality of sample information corresponding to the experiment board number, and the plurality of sample information are respectively the sample information of the plurality of samples;

the information determining module is used for determining sample release information corresponding to the samples according to the sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result;

and the report issuing module is used for responding to the report issuing instruction under the condition that the report issuing instruction is acquired, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to the sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises the sample issuing information corresponding to one sample.

In a third aspect, there is provided a computer device comprising a memory and one or more processors for executing one or more computer programs stored in the memory, the one or more processors, when executing the one or more computer programs, causing the computer device to implement the report issuing method of the first aspect described above.

In a fourth aspect, there is provided a computer-readable storage medium storing a computer program comprising program instructions which, when executed by a processor, cause the processor to perform the report issuing method of the first aspect.

The application can realize the following technical effects: batch generation and release of sample detection reports of a plurality of samples corresponding to one detection pore plate are realized based on one experiment plate number, and the report release efficiency can be improved; in addition, because the sample release information of a plurality of samples of one detection pore plate is directly determined according to one experimental plate number, the detection personnel can conveniently check and mark the sample detection results detected in the same batch, and great convenience is brought to the checking work of sample detection.

Drawings

Fig. 1 is a flowchart of a report issuing method according to an embodiment of the present application;

2A-2B are schematic diagrams of an interaction interface in a laboratory management system provided by an embodiment of the application;

3A-3B are schematic diagrams of sample information entry processes provided by embodiments of the present application;

fig. 4 is a schematic structural diagram of a report issuing device according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of a computer device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

The technical scheme of the application is applicable to a large-batch sample detection scene, especially to a large-batch nucleic acid sample detection scene, for example, the technical scheme is applicable to comprehensive nucleic acid detection work of the new coronavirus. For ease of understanding, the overall nucleic acid detection procedure will be described first.

1. Specimen collection

In the sample collection link, a person needing nucleic acid detection arrives at a nucleic acid sampling place to sample nucleic acid, and after the nucleic acid sampling person collects samples (throat swab or nose swab samples and the like), the collected samples are arranged in a sample storage tube with a bar code, wherein the bar code of the sample storage tube is associated with user information, and the user information can be inquired through the bar code information.

2. Specimen transfer

In the specimen transfer link, after the bar code information of each specimen is checked one by a transfer staff, the specimen is put into a special and tightly-packaged transfer box and transferred to a detection laboratory.

3. Specimen signing and recording

After the specimen arrives at the laboratory, the receiving personnel in the laboratory sign off, and then the bar codes on the sample storage tube are input into the information system one by one.

4. Sample adding and extracting

And (3) a sample is transferred to the sample plate from the sample storage tube by a tester in the laboratory by using a sample adding gun to extract the nucleic acid.

5. Dispensing reagent

Laboratory testers perform amplification reagent preparation according to the number of samples, and reagents are prepared into small centrifuge tubes (i.e., EP tubes, generally eight-tube sets), wherein the number of parts of reagents is equal to the number of samples.

6. Spotting is carried out

The laboratory tester adds the extracted nucleic acid into the reaction system.

7. Amplification on machine

And putting the nucleic acid added with the amplification reagent into an amplification instrument for amplification in batches, and waiting for a nucleic acid detection result.

8. Nucleic acid detection result recording and report issuing

After the nucleic acid detection results are obtained by amplification, laboratory personnel check the nucleic acid detection results of the samples on the amplification plate one by one according to the pore plate, then enter the system and issue reports one by one.

In the step of recording the nucleic acid detection result and issuing the report, laboratory personnel need to check the nucleic acid detection results of the samples on the amplification plate one by one according to the pore plate and then record the result into the system, and record the nucleic acid detection result of each pore on the amplification plate and the sample information of the samples into the system after associating, so that on one hand, the problem of association error may occur in the association process; on the other hand, the mode of recording and publishing one by one is not beneficial to the publishing efficiency of the report.

In view of the above, the present application provides a report issuing method, in which an experiment board number is associated with sample information of a sample on a detection pore board in advance, when a detection result of the sample on the detection pore board is obtained, a plurality of pieces of sample information corresponding to the experiment board number are obtained, and sample issuing information corresponding to each of the plurality of pieces of sample information is determined, where the sample issuing information includes user information and a sample detection result, and finally a sample detection report corresponding to the sample on the detection pore board is generated according to the sample issuing information corresponding to each of the plurality of pieces of sample information, which is equivalent to inputting the sample detection result and issuing the sample detection report in batch according to the detection pore board, thereby improving efficiency of report issuing; moreover, the sample detection results are input and the sample detection reports are issued in batches according to the detection pore plates, so that detection personnel can conveniently check and mark the sample detection results detected in the same batch, and great convenience is brought to the checking work of sample detection.

The technical solution of the present application is specifically described below.

Referring to fig. 1, fig. 1 is a flowchart of a report issuing method provided in an embodiment of the present application, where the method is applicable to a laboratory management system, where the laboratory management system may be used to perform unified information management on various detection instruments or detection devices in a laboratory; as shown in fig. 1, the method comprises the steps of:

s101, acquiring an experiment plate number.

And S102, inquiring a plurality of sample information corresponding to the experiment plate number, wherein the plurality of sample information are respectively the sample information of a plurality of samples.

And S103, determining sample release information corresponding to each of the plurality of samples according to the plurality of sample information corresponding to the experiment plate number.

And S104, under the condition that the report issuing instruction is acquired, responding to the report issuing instruction, and generating a plurality of sample detection reports corresponding to the target detection pore plate according to a plurality of sample detection reports corresponding to the plurality of samples.

In the embodiment of the present application, the test plate number is used to indicate a detection batch of a plurality of samples corresponding to a target detection pore plate, where the target detection pore plate is any one detection pore plate used in a sample detection process, and the target detection pore plate may specifically be an amplification plate used for carrying samples during batch amplification in the above-mentioned on-machine amplification link. The plurality of samples corresponding to the target detection pore plate refer to a plurality of samples which are placed on the target detection pore plate for sample detection. Specifically, the plurality of samples corresponding to the target detection well plate may be a plurality of samples that are placed on the same amplification plate for performing on-machine amplification during sample detection. It can be understood that the assay plate number is used to uniquely indicate a batch of samples placed on the same assay well plate, and when performing sample assay, samples placed on different assay well plates have different corresponding assay plate numbers.

In some possible cases, the experiment plate number may be generated in a sample information entry process (such as the aforementioned specimen signing and entry link) and associated with sample information of the sample, and each time entry of a batch of sample information whose number matches with the detection specification parameters of the detection orifice plate is completed, an experiment plate number is generated, and the experiment plate number and the entered multiple sample information are stored in an associated manner, so as to establish a corresponding relationship between multiple sample information and one experiment plate number, and then, the subsequent detection may be directly performed in batches based on the experiment plate number. The sample information refers to information associated with user information. By inputting the sample information into the laboratory management system, the laboratory management system can pull the corresponding user information from the sample information acquisition system according to the sample information, so that the sample detection result corresponding to the sample information is subsequently associated with the user information, and the nucleic acid detection result of the user is obtained. In particular, the sample information may refer to the barcode information on the sample holding tube described above.

In a specific implementation, for the step S101, the experiment board number may be obtained by obtaining input information of the user through the sample result entry interface. Illustratively, referring to the graphical interface shown in fig. 2A, when a user opens interface J1 or interface J2 in fig. 2 on the lab management system and enters a lab board number on interface J1 or interface J2, the lab board number is obtained.

Specifically, in step S102, a plurality of sample information corresponding to the experiment board number may be searched according to a correspondence relationship between a plurality of sample information and the experiment board number, which is pre-established in the sample information entry process.

Optionally, after the sample information of the multiple samples is obtained through the query, the queried sample information of the multiple samples can be displayed through a graphical interface. The method further includes, after the step S102: and displaying a sample information detailed interface, wherein the sample information detailed interface is used for displaying the inquired plurality of sample information corresponding to the experiment plate number, and the plurality of sample information corresponding to the experiment plate number are arranged in the sample information detailed interface according to the arrangement mode of the plurality of samples corresponding to the target detection plate on the target detection pore plate.

Here, the fact that the plurality of sample information are arranged in the display sample information detail interface in such a manner that the plurality of samples are arranged on the target detection well plate means that the arrangement manner and the arrangement order of the plurality of sample information in the display sample information detail interface are the same as those of the plurality of samples on the target sample detection well plate. For example, referring to the interface J3 in fig. 2B, in the interface J3, the sample information SA0001 is arranged at the table corresponding to C3, and then, it indicates that the sample corresponding to the sample information SA001 is arranged at the C3 hole of the detection well plate.

After the sample information of a plurality of samples corresponding to one detection pore plate is inquired, the interface is requested in detail by displaying the sample information, and the sample information can be intuitively corresponding to the samples on the detection pore plate because the sample information is arranged according to the arrangement mode of the samples on the detection pore plate, so that a user can conveniently mark and track the samples, and the sample information does not need to be searched and determined one by one. For example, when the user determines that the sample at the C3 hole of the detection hole plate is positive or suspected to be positive and needs to be reviewed, the user may directly mark the sample information at the C3 form in the sample information detail interface.

Further optionally, the instruction input by the user may be acquired through the sample information detail request interface, and the sample information may be modified, edited, marked, or the like according to the instruction input by the user. In a possible implementation scenario, when a review instruction for first sample information is acquired through a sample information detail request interface, a review reason of the first sample information is recorded, and a first issue mark is added to the first sample information, where the first issue mark is used to indicate that a sample detection report corresponding to the first sample information is not issued when a plurality of sample detection reports corresponding to a target detection orifice plate are issued. For example, when the user checks the sample information SA001 at the C3 table in the interface J3 and selects the reason of "abnormal amplification" in the review reason input box in the interface J3, it is determined that a review flag instruction for the sample information at the C3 table is acquired, the review reason for the sample information at the C3 table is set to "abnormal amplification", a first issue flag is added to the sample information at the C3 table, and then, when a sample detection report corresponding to the sample information in the J3 interface is issued, a detection report corresponding to the sample information SA001 at the C3 table is not issued.

In the embodiment of the present application, the sample release information refers to information related to sample detection that needs to be released, where one sample corresponds to one sample release information, and one sample release information may include user information corresponding to one sample and a sample detection result. The user information corresponding to the sample refers to information of a user to which the sample belongs, the user information corresponding to the sample can be used for uniquely indicating the user, and the user information corresponding to the sample can specifically include a name, an identification number, a mobile phone number and the like.

In a possible embodiment, the sample distribution information corresponding to each of the plurality of samples may be determined as follows:

f1, generating a sample detection result for each sample information in the plurality of sample information according to the preset result dictionary, and acquiring user information corresponding to each sample information in the plurality of sample information.

Here, the preset result dictionary is a dictionary preset in the laboratory management system by a user for generating a sample detection result. The preset result dictionary may specifically include contents of "negative", "positive", and the like. In generating the sample detection result for each sample information, a default result in the preset result dictionary may be set as the sample detection result for each sample information. For nucleic acid sample detection, "negative" is a default result, and a sample detection result is generated for each sample information in the plurality of sample information according to a preset result dictionary, and means: and setting the sample detection result of each sample information as negative.

And F2, determining sample distribution information corresponding to each of the plurality of samples according to the user information corresponding to each sample information and the sample detection result of each sample information.

The user information corresponding to each sample information and the sample detection result of each sample information can be directly used as the sample release information.

By generating the sample detection result for each sample information according to the preset result dictionary, batch entry of the sample detection results is realized, users do not need to enter one by one, and the entry efficiency of the sample detection results can be improved.

Optionally, the sample issuance information may further include one or more of a sample type, a reagent protocol, a reagent lot number, or an experiment number.

Optionally, after the sample publishing information corresponding to each of the plurality of samples is determined, the sample publishing information corresponding to each of the plurality of samples may be displayed through a graphical interface. The method further includes, after the step S103: and displaying a sample publishing interface, wherein the sample publishing interface is used for displaying sample publishing information corresponding to each of the plurality of samples.

The arrangement mode and the arrangement sequence of the sample release information corresponding to each of the plurality of samples in the sample release interface may be the same as those of the plurality of sample information in the sample information detail interface, and are the same as those of the plurality of samples in the target sample detection pore plate, that is, compared with the sample information detail interface, the sample release interface also displays sample release information such as user information and sample detection results. Optionally, the sample publishing information corresponding to each of the plurality of samples may also be arranged in the sample publishing interface according to the entry sequence of the sample information. Illustratively, the sample publishing interface may be as shown in interface J4 in FIG. 2.

Further optionally, the instruction input by the user may be obtained through the sample issuing interface, and the sample issuing information may be modified, edited, marked, or the like according to the instruction input by the user.

In a possible implementation scenario, in a case that a content modification instruction for first sample release information is obtained, the first sample release information is modified according to the content modification instruction for the first sample release information, and the content modification instruction may be used to indicate that at least one of a release language type of the first sample release information, a sample detection result corresponding to the first sample release information, a sample type corresponding to the first sample release information, a reagent scheme corresponding to the first sample release information, a reagent batch number corresponding to the first sample release information, or an experiment number corresponding to the first sample release information is modified. The sample issuing language type refers to a language type used in the sample detection report, such as Chinese, English and the like, when the sample issuing information is issued through the sample detection report; the sample type refers to the collection mode of the sample; the reagent scheme and the reagent batch number refer to the scheme and the batch number adopted by the sample detection; the test number refers to a number written for a sample during the test, and is used to uniquely indicate the sample on the test well plate.

For example, referring to the interface J4 in fig. 2B, when the user selects the sample distribution information in the first row and selects "change experiment number", it is determined that the content modification instruction for the sample distribution information in the first row is acquired, and the experiment number of the sample distribution information in the first row is modified according to the experiment number input by the user; for another example, when the user selects the sample issuing information of the second row and changes the result, it is determined to acquire the content correction instruction for the sample issuing information of the second row, and the sample detection result of the sample issuing information of the second row is modified according to the sample detection result input by the user. By providing the content correction function, the user can revise and correct the sample release information, so that the accuracy of the sample release information can be ensured.

In another possible implementation scenario, in the case that a review instruction for the first sample issue information is acquired, a second issue flag is added to the first sample information, where the second issue flag is used to indicate that the sample detection report corresponding to the first sample issue information is not issued when the multiple sample detection reports corresponding to the target detection orifice plate are issued.

By displaying the sample information publishing interface and acquiring the specific content modified by the user through the sample information publishing interface, the user can modify the sample publishing information, so that different requirements can be met.

Optionally, in some possible scenarios, the user may also preview the sample release information in the laboratory management system. The method further includes, after the step S103: and under the condition that a report preview instruction for the second sample issuing information is acquired, generating a sample detection report corresponding to the second sample issuing information and performing preview display. Specifically, referring to an interface J1 in fig. 2, when the user selects the sample issue information in the first row and selects "preview report sheet", it is determined to acquire a preview report instruction for the sample issue information in the first row, and then a sample detection report corresponding to the second sample information is generated according to the second sample issue information.

In the embodiment of the application, the report issuing instruction is used for indicating batch issuing of the report, wherein the report issuing instruction can be acquired through the sample issuing interface. Specifically, before the report issuing instruction is acquired, if a rechecking instruction for any sample is not acquired, a sample detection report for each sample may be generated and issued according to sample issuing information corresponding to each sample; and if a review instruction for the target sample is acquired, generating and issuing sample detection reports corresponding to other samples except the target sample in the plurality of sample information according to the sample issuing information corresponding to the plurality of samples. The review instruction of the target sample can be obtained through the sample information detailed request interface, and can also be obtained through the sample issuing interface.

In the technical scheme, sample information of a plurality of samples corresponding to one detection pore plate is inquired according to the number of the experiment plate, sample issuing information of the plurality of samples is determined according to the sample information of the plurality of samples, the sample issuing information comprises user information and sample detection results, and then under the condition that a report issuing instruction is obtained, a plurality of sample detection reports corresponding to one detection pore plate are generated and issued according to the sample issuing information of the plurality of samples. Batch generation and release of sample detection reports of a plurality of samples corresponding to one detection pore plate are realized based on one experiment plate number, and the report release efficiency can be improved; in addition, because the sample release information of a plurality of samples of one detection pore plate is directly determined according to one experimental plate number, the detection personnel can conveniently check and mark the sample detection results detected in the same batch, and great convenience is brought to the checking work of sample detection.

Optionally, in some possible cases, in order to manage the samples and the sample information, in the process of inputting the sample information, a sample adding table may be generated for each batch of input sample information according to the input condition of the sample information. The above method may further comprise the steps of:

and D1, when a sample entry instruction for the virtual sample rack is acquired, responding to the sample entry instruction, and entering the acquired sample information into the virtual sample rack.

D2, counting the sample information recorded into the virtual sample rack, generating an experiment board number for the sample information recorded into the virtual sample rack according to a preset board number generation rule under the condition that the counting value reaches the maximum recorded number of the virtual sample rack, and generating a sample adding table corresponding to the virtual sample rack according to the sample information and the experiment board number recorded into the virtual sample rack.

In the embodiment of the application, the virtual sample rack is a virtual sample rack in a laboratory management system, the virtual sample rack is used for inputting sample information, and can correspond to the sample rack for placing the sample corresponding to the sample information in the real environment, wherein the virtual sample rack can be created in the laboratory management system by a user in advance. In a specific implementation scenario, after a user inputs sample information of a sample into a laboratory management system in the laboratory management system, the sample with the input sample information is placed on a real sample rack, and correspondingly, a virtual sample rack corresponding to the real sample rack is correspondingly created in the laboratory management system.

In a specific implementation manner, when it is detected that a user selects a virtual sample rack on a laboratory management system, opens a sample receiving interface, and scans and inputs barcode information on the sample receiving interface, it is determined that a sample input instruction for the virtual sample rack is obtained, the scanned barcode information is stored, and the barcode information is input to the virtual sample rack.

In the embodiment of the application, each virtual sample rack is provided with the maximum input number, and the maximum input number refers to the maximum number of sample information input to the virtual sample rack. The maximum input number of the virtual sample racks is set according to preset quality control parameters and detection specification parameters of the sample detection equipment. The quality control parameters are used for indicating the number of reference samples and reference samples required in the sample detection process, wherein the quality control parameters specifically include negative quality control (referring to the reference samples used as negative controls) and negative quality control number (referring to the number of reference samples used as negative controls), positive quality control (referring to the reference samples used as positive controls) and positive quality control number (referring to the number of reference samples used as positive controls), blank control and blank control number, and other parameters used for quality control in the nucleic acid detection process. The detection specification parameter of the sample detection device refers to the number of samples detectable by the sample detection device for sample detection at one time, wherein the samples detectable by the sample detection device may include a truly acquired sample (i.e., a sample corresponding to the sample information) and a reference sample. In one embodiment, the assay specification parameters of the sample testing device are characterized by the specification of the assay consumable used by the sample testing device, for example, in the sample testing process, the sample application plate used for sample application and the amplification plate used in the amplification instrument are 96-well plates, and then the specification parameters of the sample testing device are 96-well plates.

In some possible scenarios, the quality control parameters and the detection specification parameters of the sample detection device may be entered into the laboratory management system before the sample information is entered, and in the case of obtaining the parameter entry instruction, the laboratory management system enters the quality control parameters and the detection specification parameters of the detection device in response to the parameter entry instruction.

In the specific implementation, a user can enter quality control parameters and set detection specification parameters of the detection equipment through a quality control quantity management module in the laboratory management system, and when the condition that the user enters the quality control parameters in the quality control quantity management module and selects the detection specification parameters of the detection equipment is detected, the laboratory management system obtains a parameter entry instruction and stores the quality control parameters entered by the user and the selected detection specification parameters of the detection equipment. Through setting up quality control quantity management module, the user can carry out nimble configuration to the quality control parameter to can match in the nucleic acid detection of different quality control demands.

In the embodiment of the application, the maximum input number of the virtual sample racks is equal to the sum of the differences of the detection specification parameters and the quality control parameters of the sample detection equipment. For example, the detection specification parameter of the sample detection device is 96 holes, and if the number of negative quality controls is 3, the number of positive quality controls is 1, and the number of blank controls is 1, the maximum input number of the virtual sample rack is 91; if the detection specification parameters of the sample detection equipment are 48 holes and the quality control parameters are unchanged, the maximum input number of the virtual sample racks is 43.

In some possible embodiments, the maximum number of entries of the virtual sample rack may be set by the user. For example, a user can automatically calculate the maximum input number of the virtual sample racks according to the quality control parameters set by the quality control number management module and the detection specification parameters of the selected detection equipment, and then set the maximum input number of the virtual sample racks by the capacity management module in the laboratory management system.

In other possible embodiments, the maximum entry number of the virtual sample racks may also be calculated by the laboratory management system according to the quality control parameters set by the user and the detection specification parameters of the detection device. For example, after a user sets quality control parameters and detection specification parameters of detection equipment on a laboratory management system, when the user creates a virtual sample rack on the laboratory management system, the laboratory management system calculates the maximum entry number of the virtual sample rack according to the quality control parameters set by the user and the detection specification parameters of the detection equipment, and sets the maximum entry number for the created virtual sample rack. Optionally, the laboratory management system may also calculate, when the user selects the virtual sample rack for sample entry, a maximum entry number according to a quality control parameter set by the user and a detection specification parameter of the detection device, and set the maximum entry number for the virtual sample rack selected by the user. Through the detection specification parameter according to matter accuse parameter and check out test set, for virtual sample frame sets up the biggest input quantity, the effect of carrying out the batching to the sample has been reached, make input to the sample information quantity and the quality control demand and the sample check out test set phase-match of virtual sample frame, thereby make input to the sample that the sample information of virtual sample frame corresponds can directly shift to and detect in the sample check out test set, need not the manual work when detecting and carry out the batching to the sample, thereby can avoid the batch mistake scheduling problem that the manual work brought in batches, carry out automatic batching to the sample and also can improve detection efficiency.

In the embodiment of the present application, the sample adding table corresponding to the virtual sample rack refers to a document for recording sample information entered into the virtual sample rack through a table, wherein the sample adding table includes all sample information entered into the virtual sample rack, and the sample information entered into the virtual sample rack is arranged in the sample adding table according to a preset sequence. The method for generating the sample adding table corresponding to the virtual sample rack comprises the following steps: and distributing and arranging the sample information recorded into the virtual sample rack in a table mode according to a preset sequence, and recording the sample information in the table. The distribution and arrangement of the tables for recording the sample information recorded into the virtual sample rack are the same as the distribution and arrangement of the detection consumables (such as the sample adding plate or the amplification plate) adopted by the sample detection equipment. Through arranging and distributing the sample information input into the virtual sample rack in a form mode according to a preset sequence, the automatic numbering of the sample information input into the virtual sample rack is realized, the arrangement and distribution mode of the form are set to be consistent with the distribution and arrangement mode of the detection consumables of the sample detection equipment, and the subsequent batch detection can be facilitated.

In the concrete implementation, in the process of inputting the sample information into the virtual sample rack, the laboratory management system counts the input sample information, and every time a user inputs one sample information, the laboratory system adds one to the count value of the sample information input into the virtual sample rack, then comparing the count value of the sample information recorded into the virtual sample rack with the maximum recorded number of the virtual sample racks, if the count value of the sample information recorded into the virtual sample rack is equal to the maximum recorded number of the virtual sample racks, indicating that the virtual sample rack is completely recorded, new sample information can not be recorded, generating a laboratory plate number for the sample information recorded into the virtual sample rack by the laboratory management system according to a preset plate number generation rule, and generating a sample adding table corresponding to the virtual sample rack according to the sample information and the experiment board number which are input into the virtual sample rack.

The experiment plate number is used for uniquely indicating the batch condition of the sample information currently input into the virtual sample rack, and all the sample information input into the virtual sample rack correspond to the same experiment plate number. In one embodiment, the plate number may be generated based on the date and lot. For example, the sample addition table has an experimental plate number LQ20210611a1681, and the sample information in the sample addition table is sample information recorded in batch 1681 at 6/11/2021.

It should be understood that the preset plate number generation rule may be any rule, as long as it is ensured that the generated test plate number can uniquely indicate the batch condition of the sample information. The experiment plate number is generated through the sample information which is currently input into the virtual sample frame, the serial numbers of the sample information input in each batch are different, the sample information can be directly detected in batches based on the experiment plate number in the subsequent detection process, the sample adding plate, the amplification plate and the like are not required to be numbered, the detection efficiency can be improved, the incidence relation between the experiment plate number and the sample information is established through the sample adding table, and the report can be conveniently released in subsequent batches.

In the technical scheme, when the acquired sample information is recorded into the virtual sample rack according to the sample recording instruction of the virtual sample rack, the sample information recorded into the virtual sample rack is counted, and when the count value reaches the maximum recording number corresponding to the virtual sample rack, the sample adding table corresponding to the virtual sample rack is generated. The sample adding table comprises sample information input to the virtual sample rack, the sample information input to the virtual sample rack is arranged in the sample adding table according to a preset sequence, and the sample information is numbered and sequenced automatically through the sample adding table; the maximum input quantity of the virtual sample rack is set according to the quality control parameters and the detection specification parameters of the sample detection equipment, under the condition that the count value reaches the maximum input quantity of the virtual sample rack, a sample adding table corresponding to the virtual sample rack is generated, the quantity of samples corresponding to the sample information in the sample adding table can be adapted to the detection specification of the detection equipment, a detection person can directly carry out batch detection on the samples according to the sample information in the sample adding table, namely, the samples can be automatically batched through the sample adding table, and the sample detection can also be fully utilized according to the sample information in the sample adding table, so that the sample information can be automatically numbered and sequenced and the samples can be automatically batched through generating the sample adding table corresponding to the virtual sample rack, and the sample detection equipment can also be fully utilized, therefore, the sample detection efficiency can be improved.

Optionally, in some possible cases, when the count value does not reach the maximum entry number, if the table generation instruction corresponding to the virtual sample rack is obtained, the sample addition table corresponding to the virtual sample rack may be generated in response to the table generation instruction.

Here, the form generation instruction is used to instruct that the entry of the sample information on the virtual sample rack is completed, and the entry of the sample information this time is ended. It is to be understood that the manner in which the sample addition table is generated in the case where the count value does not reach the maximum entry number coincides with the manner in which the sample addition table is generated in the case where the count value reaches the maximum entry number, and the only difference is that the number of pieces of sample information in the sample addition table generated in the case where the count value does not reach the maximum entry number is less than the count value reaches the maximum entry number.

Wherein the table generation instruction may be issued by a user. Specifically, a user can send a form generation instruction through the sample receiving interface, and when the user clicks a human-computer interaction component such as "enter complete" or "generate form" on the sample receiving interface, which is used for indicating that no more sample information is entered on the virtual sample rack, the laboratory management system obtains the form generation instruction corresponding to the virtual sample rack.

By means of generating the sample adding table according to the table generation instruction, the sample adding table can be generated when the number of the current samples cannot meet the detection specification parameters of the sample detection equipment or a user is in case of accident, and therefore all samples can be detected.

Optionally, in some possible cases, the sample addition table may further include an experiment number, and before generating the sample addition table corresponding to the virtual sample rack, the method further includes acquiring an experiment group identifier, where the experiment group identifier is used to indicate an experiment detection group currently performing sample detection; and generating an experiment number for each sample information recorded into the virtual sample rack according to the recording sequence of the sample information recorded into the virtual sample rack and the experiment number template corresponding to the experiment team identification.

The experiment team identification and the experiment number template are information preset in the laboratory management system, different detection teams have different experiment team identifications and different experiment team identifications, and correspond to different experiment number templates. The user can configure the experiment team identification and the experiment number template corresponding to the experiment team identification in the laboratory management system, and the laboratory management system correspondingly stores the experiment team identification and the experiment number template configured by the user. In the concrete implementation, before sample information is input, when a person detecting a team selects a laboratory team identifier in a laboratory management system, the laboratory management system inquires a laboratory number template corresponding to the laboratory team identifier. And then generating an experiment number for each piece of sample information recorded into the virtual sample rack in the process of recording the sample information. Wherein, the experiment number of each sample information is continuous and unique in the sample table.

In a possible implementation manner, the experiment number template corresponding to the experiment team identification and the input sequence of the sample information input into the virtual sample rack can be combined to be used as the experiment number of each sample information input into the virtual sample rack. For example, if the experiment number template corresponding to the experiment team identification is "SYA", the sample information experiment number in the order of 1 is SYA01, the sample information experiment number in the order of 2 is SYA02, the sample information experiment number in the order of 3 is SYA03, and so on.

The experiment number is generated for each input sample information according to the input sequence of the sample information, so that the input sample information is ordered in the sample adding table, subsequent verification and checking can be facilitated, the experiment number is generated by the experiment detection team according to the current sample detection, and the sample can be conveniently tracked and positioned for subsequent review.

Optionally, in some possible cases, the sample addition table further includes quality control information, and before generating the sample addition table, the method further includes: and generating quality control information corresponding to the quality control parameters.

The quality control information refers to information used as a reference sample for quality control comparison in an experimental detection process, and the accuracy of detection can be ensured by setting the reference sample for quality control comparison in the experimental detection process. Generating the quality control information corresponding to the quality control parameters means setting a corresponding amount of quality control information in a table for recording the sample information entered into the virtual sample rack according to the quality control parameters. For example, the quality control parameters set by the user in the quality control quantity management module are: if the number of negative quality controls is 3, the number of positive quality controls is 1, and the number of blank controls is 1, it is necessary to set 3 negative quality control bits, 1 positive quality control bit, and 1 blank control bit in the table for recording the sample information entered into the virtual sample rack.

Through generating the quality control information corresponding to the quality control parameters and adding the quality control information into the sample adding table, a detector can be reminded to add a quality control product according to the quality control information in the sample adding table, so that the accuracy of sample detection corresponding to the sample adding table in the experimental process can be ensured.

Optionally, in some possible cases, the quality control information in the sample addition table may be generated after the sample information is randomly entered into the virtual sample rack according to the quality control parameters in the process of entering the sample information into the virtual sample rack. When a user inputs one piece of quality control information, a blank tube (a blank sample tube for prompting a detector to add a corresponding reference sample) carrying the quality control information is placed on the sample rack. In this case, in a possible implementation, a specific implementation process of entering the acquired sample information into the virtual sample rack may be as shown in fig. 3A, and includes the following steps:

and A1, randomly generating quality control positions for the virtual sample rack according to the quality control parameters.

Specifically, the number of various pieces of quality control information to be entered into the virtual sample rack may be determined according to the quality control parameters, and the positions whose number is the total number are randomly selected in the virtual sample rack as quality control positions according to the total number of the pieces of quality control information to be entered into the virtual sample rack. The quality control position is used for inputting quality control information, and the position on the real sample rack corresponding to the quality control position is used for placing a reference sample.

For example, the quality control parameters include { negative quality control: 3}, { positive quality control: 1}, { blank: 1, the total amount of the quality control information to be input into the virtual sample rack is 5, and 5 positions are randomly selected in the virtual sample rack to serve as quality control positions for inputting the quality control information.

And A2, taking the ith position of the virtual sample rack as the recording position.

Here, the initial value of i is 1.

And A3, judging whether the recording position is a quality control position.

If the recording position is a quality control position, executing the step A4; if the recorded position is not the quality control position, step A7 is executed.

A4, sending out a first prompt.

Here, the first prompt is used to prompt the user to enter the quality control information, that is, to prompt the user to place the blank tube carrying the quality control information into the position corresponding to the quality control position on the sample rack. For example, if the 3 rd position on the virtual sample rack is the quality control position, the first prompt is used for prompting the user to place the blank tube carrying the quality control information into the 3 rd position on the sample rack.

And A5, judging whether the quality control information input by the user is acquired.

In the case where the quality control information entered by the user is acquired, step a6 is executed. In the real environment, when a user inputs quality control information, the blank tube carrying the quality control information is placed on the sample rack at a position corresponding to the quality control position.

And A6, inputting the quality control information input by the user to the input position, and executing the step A9.

And A7, judging whether the sample information input by the user is acquired.

In the case where the sample information entered by the user is acquired, step A8 is executed. In a real scene, when a user inputs sample information, a sample tube corresponding to the sample information is placed on a sample rack.

And A8, inputting the sample information input by the user to the input position, and executing the step A9.

And A9, judging whether the recording position is the last position of the virtual sample rack.

If the recording position is the last position of the virtual sample rack, ending the recording, and executing the sample adding table corresponding to the virtual sample rack generated in the step S102. If the recorded position is not the last position of the virtual sample rack, step A10 is performed.

And A10, taking the (i +1) th position of the virtual sample rack as an entry position, and returning to execute the step A3.

In the process from A1 to A10, the quality control position is randomly generated for the virtual sample rack in advance, and when the input position is the quality control position, a prompt for instructing the user to input the quality control information is sent, so that the user can input the quality control information in the process of inputting the sample information, and a blank tube with a reference sample on the sample rack is ensured.

In another possible implementation manner, a specific implementation process of entering the acquired sample information into the virtual sample rack may be as shown in fig. 3B, and includes the following steps:

and B1, taking the ith position of the virtual sample rack as an entry position, and acquiring the information entered by the user.

And B2, judging whether the information input by the user is sample information.

If the information input by the user is sample information, executing step B3; if the recorded information is quality control information, step B6 is executed.

And B3, judging whether the number of the sample information recorded into the virtual sample rack reaches the maximum recorded number.

In the embodiments of the present application, the meaning of the maximum number of entries of the virtual sample rack can refer to the foregoing description.

If the number of the sample information recorded into the virtual sample rack reaches the maximum recording number, executing the step B5; if the number of the sample information recorded into the virtual sample rack does not reach the maximum recorded number, step B4 is executed.

And B4, inputting the sample information input by the user to the input position, and executing the step B9.

B5, sending out a first prompt.

Here, the related meaning of the first hint may refer to the foregoing description. After the first prompt is sent, the information entered by the user can be obtained again, and the step B7 is executed if the information entered by the user is the quality control information.

And B6, judging whether the quantity of the quality control information recorded into the virtual sample rack reaches the quantity sum corresponding to the quality control parameters.

Here, the number corresponding to the quality control parameter and the sum of the numbers of all reference samples indicated by the quality control parameter. The sum of the quantity corresponding to the quality control parameters is equal to the total quantity of the quality control information to be recorded into the virtual sample rack. If the quantity of the quality control information recorded into the virtual sample rack reaches the sum of the quantity corresponding to the quality control parameters, executing the step B8; if the number of the quality control information recorded into the virtual sample rack does not reach the sum of the numbers corresponding to the quality control parameters, step B7 is executed.

B7, inputting the quality control information input by the user to the input position, and executing the step B9.

B8, sending out a second prompt.

Here, the second prompt is used to prompt the user to enter sample information, i.e., to prompt the user to place a sample tube on the sample rack. After the second prompt is sent, the information entered by the user can be obtained again, and if the information entered by the user is sample information, step B4 is executed.

And B9, judging whether the recording position is the last position of the virtual sample rack.

If the recording position is the last position of the virtual sample rack, the recording is finished, and the step S103 is executed. If the recorded position is not the last position of the virtual sample rack, step B10 is performed.

And B10, taking the (i +1) th position of the virtual sample rack as the recording position.

In the processes from B1 to B11, a user determines whether to enter sample information or quality control information, the sample information and the quality control information entered by the user are monitored, and corresponding prompts are sent, so that the entered sample information and the quality control information can meet quality control parameters and detection specification parameters of sample detection equipment, blank tubes with reference samples on sample racks are ensured to be placed on the sample racks, and in the subsequent detection process, sample detection personnel can add corresponding reference samples according to the quality control information of the blank tubes on the sample racks, and the situation that the reference samples are not added is avoided; the user can automatically input the sample information or the quality control information, so that great flexibility is brought to the user for inputting the information.

Optionally, before the step a6 or the step B7 is executed, the quality control information entered into the user may also be determined so that the type of the reference sample indicated by the quality control information matches the quality control parameters. Before the step a6 or the step B7 is executed, the following steps may be further included:

and C1, determining the type of the reference sample corresponding to the quality control information input by the user.

And C2, judging whether the first quantity reaches the second quantity indicated by the quality control parameter.

Here, the first number refers to the number of quality control information corresponding to the reference sample type that has been entered into the virtual sample rack. For example, if the type of the reference sample corresponding to the quality control information entered by the user is a reference sample used as a negative control, the first number refers to the number of negative quality controls entered into the virtual sample rack.

The second number refers to the number of reference samples belonging to the reference sample type indicated by the quality control parameter. For example, if the type of the reference sample corresponding to the quality control information entered by the user is a reference sample used as a negative control, the second number refers to the negative quality control number.

Wherein, in the case that the first number has reached the second number indicated by the quality control parameter, step C3 is executed; in the case that the first quantity does not reach the second quantity indicated by the quality control parameter, the above step a6 or step B7 is executed.

C3, sending out a third prompt.

And the third prompt is used for prompting the user to enter other quality control information, wherein the other quality control information refers to the quality control information corresponding to the reference sample which does not belong to the type of the reference sample. And after the third prompt is sent, the information input by the user can be obtained again, and under the condition that the information input by the user is other quality control information, the other quality control information is input to the input position.

The quality control information input by the user can be ensured to be matched with the quality control parameters by monitoring the quantity of the quality control information input by the user, so that the type of a blank tube placed on the sample rack by the user is ensured to be matched with the quality control parameters.

The method of the present application is described above, and in order to better carry out the method of the present application, the apparatus of the present application is described next.

Referring to fig. 4, fig. 4 is a schematic structural diagram of a report issuing device provided in an embodiment of the present application, where the report issuing device may be a part of a laboratory management system. As shown in fig. 4, the report distribution apparatus 30 includes:

an obtaining module 301, configured to obtain an experiment plate number, where the experiment plate number is used to indicate a detection batch of multiple samples corresponding to a target detection pore plate;

a query module 302, configured to query a plurality of sample information corresponding to the experiment board number, where the plurality of sample information are sample information of the plurality of samples, respectively;

an information determining module 303, configured to determine sample release information corresponding to each of the multiple samples according to the multiple pieces of sample information, where one piece of sample release information includes user information corresponding to one sample and a sample detection result;

the report issuing module 304 is configured to, in a case that a report issuing instruction is obtained, respond to the report issuing instruction, and generate and issue a plurality of sample detection reports corresponding to the target detection pore plate according to sample issuing information corresponding to each of the plurality of samples, where one sample detection report includes sample issuing information corresponding to one sample.

In one possible design, the information determining module 303 is specifically configured to: generating a sample detection result for each sample information in the plurality of sample information according to a preset result dictionary, and acquiring user information corresponding to each sample information in the plurality of sample information; and determining sample release information corresponding to the plurality of samples according to the user information corresponding to the sample information and the sample detection result of the sample information.

In one possible design, a sample release message further includes a sample type, a reagent protocol, a reagent lot number, and/or an assay number; the report distribution device 30 further includes: a modifying module 305, configured to modify first sample release information according to a content modifying instruction when the content modifying instruction for the first sample release information is obtained, where the content modifying instruction is used to instruct to modify at least one of a release language type of the first sample release information, a sample detection result corresponding to the first sample release information, a sample type corresponding to the first sample release information, a reagent scheme corresponding to the first sample release information, a reagent batch number corresponding to the first sample release information, or an experiment number corresponding to the first sample release information

The report distribution device 30 further includes: a display module 306, configured to display a sample information detail interface, where the sample information detail interface is configured to display the plurality of sample information, and the plurality of sample information are arranged in the sample information detail interface according to a manner that the plurality of samples are arranged on the target detection well plate.

In one possible design, the report issuing module 304 is specifically configured to: when a review instruction for a target sample in the plurality of samples is acquired, generating and issuing a sample detection report corresponding to other samples except the target sample in the plurality of samples according to sample issuing information corresponding to each of the plurality of samples, wherein the review instruction is used for instructing to review a sample detection result corresponding to the target sample.

In one possible design, the display module 306 is further configured to: and under the condition that a report preview instruction for second sample issuing information is acquired, generating a sample detection report corresponding to the second sample issuing information and performing preview display.

It should be noted that, for what is not mentioned in the embodiment corresponding to fig. 4, reference may be made to the description of the foregoing method embodiment, and details are not described here again.

According to the device, the sample information of a plurality of samples corresponding to one detection pore plate is inquired according to the experiment plate number, the sample issuing information of the plurality of samples is determined according to the sample information of the plurality of samples, the sample issuing information comprises user information and sample detection results, and then under the condition that a report issuing instruction is obtained, a plurality of sample detection reports corresponding to one detection pore plate are generated and issued according to the sample issuing information of the plurality of samples. Batch generation and release of sample detection reports of a plurality of samples corresponding to one detection pore plate are realized based on one experiment plate number, and the report release efficiency can be improved; in addition, because the sample release information of a plurality of samples of one detection pore plate is directly determined according to one experimental plate number, the detection personnel can conveniently check and mark the sample detection results detected in the same batch, and great convenience is brought to the checking work of sample detection.

Referring to fig. 5, fig. 5 is a schematic structural diagram of a computer device provided in an embodiment of the present application, where the computer device 40 includes a processor 401 and a memory 402. The processor 401 is connected to the memory 402, for example, the processor 401 may be connected to the memory 402 through a bus.

The processor 401 is configured to support the computer device 40 to perform the corresponding functions in the methods in the above-described method embodiments. The processor 401 may be a Central Processing Unit (CPU), a Network Processor (NP), a hardware chip, or any combination thereof. The hardware chip may be an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (PLD), or a combination thereof. The PLD may be a Complex Programmable Logic Device (CPLD), a field-programmable gate array (FPGA), a General Array Logic (GAL), or any combination thereof.

The memory 402 is used to store program codes and the like. Memory 402 may include Volatile Memory (VM), such as Random Access Memory (RAM); the memory 402 may also include a non-volatile memory (NVM), such as a read-only memory (ROM), a flash memory (flash memory), a Hard Disk Drive (HDD) or a solid-state drive (SSD); the memory 402 may also comprise a combination of memories of the kind described above.

Processor 401 may call the program code to perform the following:

acquiring an experiment plate number, wherein the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to a target detection pore plate;

inquiring a plurality of sample information corresponding to the experiment board number, wherein the plurality of sample information are respectively the sample information of the plurality of samples;

determining sample release information corresponding to the plurality of samples according to the plurality of sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result;

and under the condition that a report issuing instruction is acquired, responding to the report issuing instruction, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises sample issuing information corresponding to one sample.

Embodiments of the present application also provide a computer-readable storage medium, which stores a computer program, where the computer program includes program instructions, and the program instructions, when executed by a computer, cause the computer to execute the method according to the foregoing embodiments.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. The storage medium may be a magnetic disk, an optical disk, a Read-Only memory (ROM), a Random Access Memory (RAM), or the like.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present application and is not to be construed as limiting the scope of the present application, so that the present application is not limited thereto, and all equivalent variations and modifications can be made to the present application.

Claims (10)

1. A report issuance method, comprising:

acquiring an experiment plate number, wherein the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to a target detection pore plate;

inquiring a plurality of sample information corresponding to the experiment board number, wherein the plurality of sample information are respectively the sample information of the plurality of samples;

determining sample release information corresponding to the plurality of samples according to the plurality of sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result;

and under the condition that a report issuing instruction is acquired, responding to the report issuing instruction, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises sample issuing information corresponding to one sample.

2. The method according to claim 1, wherein the determining, according to the plurality of sample information, sample distribution information corresponding to each of the plurality of samples comprises:

generating a sample detection result for each sample information in the plurality of sample information according to a preset result dictionary, and acquiring user information corresponding to each sample information in the plurality of sample information;

and determining sample release information corresponding to the plurality of samples according to the user information corresponding to the sample information and the sample detection result of the sample information.

3. The method of claim 1, wherein one sample distribution information further comprises a sample type, a reagent protocol, a reagent lot number, and/or an experiment number;

before generating and publishing a plurality of detection reports corresponding to the target detection pore plate according to the sample publishing information corresponding to the plurality of samples, the method further includes:

modifying first sample issuing information according to a content modification instruction under the condition that the content modification instruction aiming at the first sample issuing information is obtained, wherein the content modification instruction is used for indicating that at least one item of a issuing language type of the first sample issuing information, a sample detection result corresponding to the first sample issuing information, a sample type corresponding to the first sample issuing information, a reagent scheme corresponding to the first sample issuing information, a reagent batch number corresponding to the first sample issuing information or an experiment number corresponding to the first sample issuing information is modified.

4. The method according to any one of claims 1 to 3, wherein after querying the plurality of sample information corresponding to the test plate number, further comprising:

and displaying a sample information detailed interface, wherein the sample information detailed interface is used for displaying the plurality of sample information, and the plurality of sample information are arranged in the sample information detailed interface according to the arrangement mode of the plurality of samples on the target detection pore plate.

5. The method according to any one of claims 1 to 3, wherein the generating and issuing a plurality of sample detection reports corresponding to the target detection well plate according to the sample issuing information corresponding to each of the plurality of samples comprises:

when a review instruction for a target sample in the plurality of samples is acquired, generating and issuing a sample detection report corresponding to other samples except the target sample in the plurality of samples according to sample issuing information corresponding to each of the plurality of samples, wherein the review instruction is used for instructing to review a sample detection result corresponding to the target sample.

6. The method according to any one of claims 1 to 3, wherein after determining sample distribution information corresponding to each of the plurality of samples according to the plurality of sample information, the method further comprises:

and under the condition that a report preview instruction for second sample issuing information is acquired, generating a sample detection report corresponding to the second sample issuing information and performing preview display.

7. A report issuing apparatus, comprising:

the acquisition module is used for acquiring an experiment plate number, and the experiment plate number is used for indicating the detection batches of a plurality of samples corresponding to the target detection pore plate;

the query module is used for querying a plurality of sample information corresponding to the experiment board number, and the plurality of sample information are respectively the sample information of the plurality of samples;

the information determining module is used for determining sample release information corresponding to the samples according to the sample information, wherein one sample release information comprises user information corresponding to one sample and a sample detection result;

and the report issuing module is used for responding to the report issuing instruction under the condition that the report issuing instruction is acquired, and generating and issuing a plurality of sample detection reports corresponding to the target detection pore plate according to the sample issuing information corresponding to the plurality of samples, wherein one sample detection report comprises the sample issuing information corresponding to one sample.

8. The apparatus of claim 7, wherein one sample distribution information further comprises a sample type, a reagent protocol, a reagent lot number and/or an experiment number;

the device further comprises:

the modification module is used for modifying first sample issuing information according to a content modification instruction under the condition that the content modification instruction aiming at the first sample issuing information is obtained, wherein the content modification instruction is used for indicating that at least one of a issuing language type of the first sample issuing information, a sample detection result corresponding to the first sample issuing information, a sample type corresponding to the first sample issuing information, a reagent scheme corresponding to the first sample issuing information, a reagent batch number corresponding to the first sample issuing information or an experiment number corresponding to the first sample issuing information is modified.

9. A computer device comprising a memory and a processor for executing one or more computer programs stored in the memory, the processor, when executing the one or more computer programs, causing the computer device to implement the method of any of claims 1-6.

10. A computer-readable storage medium, characterized in that the computer-readable storage medium stores a computer program comprising program instructions that, when executed by a processor, cause the processor to carry out the method according to any one of claims 1-6.

Images