CN110874521B - Analyzer, sample numbering method thereof and storage medium - Google Patents

Abstract

The analyzer, the sample numbering method and the storage medium thereof provided by the invention are used for responding to an instruction of editing the mark number of a sample input by a user and receiving the mark number input by the user; the mark number is used for numbering the samples; judging whether the mark number is the mark number of the analyzed sample, if so, prompting the mark number input by the user to be a repeated mark number; otherwise, taking the mark number input by the user as the initial mark number, and numbering the samples to be analyzed in sequence according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed. Because the numbering rule is certain, whether each identification number is correct or not is closely related to the initial identification number, and the probability of occurrence of the wrong sample identification number is reduced by judging whether the identification number input by a user is the identification number of the analyzed sample or not.

Description

Analyzer, sample numbering method thereof and storage medium

Technical Field

The invention relates to the field of medical instruments, in particular to an analyzer, a sample numbering method thereof and a storage medium.

Background

At present, for some hospitals with conditions lacking, the condition that a bar code label is printed and attached to a test tube is not provided. These hospitals will therefore typically track the test results of blood samples using a serial number as the sample's flag number (sample number), starting with a "1" every day, and increasing by +1 for each sample increase. As shown in fig. 1, in view of this rule, a hospital physician typically uses an "auto-increment" sample number rule on the hematology analyzer, i.e., sets the starting sample number to "1" for the day, and automatically increments the sample number by +1 to correspond to the incremented running water number each time the hematology analyzer analyzes a sample.

In practice, the physician will often modify the starting sample number to retest the previous sample due to abnormal aspiration or other alarms associated with a portion of the blood sample. When the doctor who processes retest changes shift, other doctors use the instrument again, at this time, because the starting number can not be known and changed before, when the doctor can not confirm whether the current starting number is reasonable, the doctor can easily analyze according to the sample serial number edited by retest before, and at this time, the starting sample number and the real serial number are not corresponding, the subsequent sample number and serial number are misplaced, so that all the tested sample information is corresponding to errors, and serious clinical result risks are caused. For example, as shown in fig. 1, when physician a has tested 1 and 2 samples, and 1 sample needs to be retested, physician a retests 1 sample after changing the next number "3" to "1", where 1 and 2 samples correspond to the serial number. If the doctor B picks up the patient after that, the doctor B sees the number of the last sample (retest sample) as "1", and then the patient can easily want to continue to measure after changing the number of the next sample to "2", the number of the sample corresponding to the patient with the serial number of 3 will become 2, the number of the sample is repeated, the subsequent sample numbers are misplaced, the detection result does not correspond to the patient, retest is needed if the patient is light, and medical accidents are easily caused if the patient is heavy.

Disclosure of Invention

The application provides an analyzer, a sample numbering method thereof and a storage medium, and aims to reduce the occurrence probability of false sample mark numbers.

According to a first aspect, in one embodiment there is provided a sample numbering method for an analyzer, comprising the steps of:

responding to an instruction of editing the mark number of the sample input by a user, and receiving the mark number input by the user; the mark number is used for numbering the samples;

Judging whether the mark number is the mark number of the analyzed sample, if so, prompting the mark number input by the user to be a repeated mark number; otherwise, taking the mark number input by the user as the initial mark number, and numbering the samples to be analyzed in sequence according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed.

According to a second aspect, there is provided in one embodiment an analyser comprising:

The sample testing device is used for analyzing a preset item of a sample and outputting an analysis result;

The man-machine interaction device is used for receiving the input and output visual information of a user;

a storage device for storing a program;

processing means for implementing the method as described above by executing the program.

According to a third aspect, an embodiment provides a computer readable storage medium comprising a program executable by a processor to implement a method as described above.

According to the analyzer, the sample numbering method and the storage medium thereof, the mark number input by a user is received in response to the instruction of editing the mark number of the sample input by the user; the mark number is used for numbering the samples; judging whether the mark number is the mark number of the analyzed sample, if so, prompting the mark number input by the user to be a repeated mark number; otherwise, taking the mark number input by the user as the initial mark number, and numbering the samples to be analyzed in sequence according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed. Because the numbering rule is certain, whether each identification number is correct or not is closely related to the initial identification number, and the probability of occurrence of the wrong sample identification number is reduced by judging whether the identification number input by a user is the identification number of the analyzed sample or not.

Drawings

FIG. 1 is a schematic diagram of a prior art analyzer numbering samples in sequential increments;

FIG. 2 is a block diagram of an analyzer according to the present invention;

FIG. 3 is a flow chart of a sample numbering method provided by the present invention;

FIG. 4 is a flowchart of step 83 in the sample numbering method according to the present invention;

FIG. 5 is a flowchart of a sample numbering method according to an embodiment of the present invention;

fig. 6 is a flowchart of another embodiment of the sample numbering method according to the present invention.

Detailed Description

The application will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, related operations of the present application have not been shown or described in the specification in order to avoid obscuring the core portions of the present application, and may be unnecessary to persons skilled in the art from a detailed description of the related operations, which may be presented in the description and general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated.

Referring to fig. 2, the analyzer provided by the present invention includes a sample testing device 40, a sample dispatching device 20, a man-machine interaction device 50, a storage device 10 and a processing device 30.

The man-machine interaction device 50 serves as an interaction interface of the analyzer with the user for receiving user input and outputting visual information, for example, receiving user input information and outputting information by acoustic, optical or electrical means. Typically, the man-machine interaction device 50 includes a display device, where the display device displays the analysis result and/or the prompt information obtained by the processing device 30, or information such as the detection progress, to the user in a visual manner. The man-machine interaction device 50 may also include a touch screen, which can both receive information input by a user and display visual information; a mouse, keyboard, trackball, joystick, etc. may also be included as an input device for the human interaction device 50 to receive information entered by the user.

The sample scheduler 20 is used to transport samples between the transfer nodes during the sample testing process.

The sample testing device 40 is used for performing a test of a preset item on the sample delivered by the sample scheduling device 20, and outputting a result, for example, outputting the test result to the processing device 30 or storing in the storage device 10.

The storage device 10 is used to store various test data, analysis results, and/or programs.

The processing device 30 is electrically connected to the sample testing device 40, the storage device 10, the sample scheduler 20 and the human interaction device 50, respectively, which may be a processor, for example. The processing device 30 is configured to receive the test data output by the sample testing device 40, analyze the test data to obtain an analysis result, or store the test data and/or the analysis result in the storage device 10. The processing means 30 is also configured to implement a sample numbering method as described below by executing the program stored by the storage means 10. For example, in the first embodiment, the processing device 30 includes an instruction acquisition module, a judgment module, a prompt module, and a numbering module.

The instruction acquisition module is used for responding to an instruction input by a user for editing the mark number of the sample, displaying an editing frame on a display interface of the man-machine interaction device 50 and enabling the user to edit the mark number; the sign number input by the user is received through the human-computer interaction device 50. The flag number is used to number the sample.

And the judging module is used for judging whether the mark number input by the user is the mark number of the analyzed sample. For example, the mark number of the sample analyzed (i.e. tested) on the same day and the corresponding analysis data (i.e. detection data) are stored in the storage device 10, the judgment module searches the storage device 10 for the mark number of the sample analyzed on the same day, compares the mark number input by the user with the mark number of the sample analyzed on the same day one by one, and if the comparison result of the mark number input by the user is the same, the mark number input by the user is considered to be the mark number of the sample analyzed, namely, the user inputs a repeated mark number; if all the mark numbers are different after comparison, the mark number input by the user is not considered to be the mark number of the analyzed sample, namely the mark number input by the user is not repeated, and the subsequent numbering work can be carried out.

The prompting module is configured to prompt, through the man-machine interaction device 50, that the sign number input by the user is a repeated sign number after the judging module obtains a conclusion that the sign number input by the user is the sign number of the analyzed sample. For example, near the edit box, the user is prompted with a colored font (e.g., red) to "repeat the sample on the same day" to avoid the examining physician setting the wrong starting flag, causing the flag to repeat. Of course, the font can also be displayed beside the mark number input by the user for prompting, and can also be changed into a pop-up dialog box for prompting.

The numbering module is used for taking the mark number input by the user as the initial mark number after the judging module obtains the conclusion that the mark number input by the user is not the mark number of the analyzed sample, and sequentially numbering the samples to be analyzed according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed. For example, the numbering module takes the mark number input by the user as the initial mark number to number the current sample to be analyzed, and starts the sample testing device 40 to detect the sample to be analyzed; after the current sample is sucked, the mark number of the next sample to be analyzed is obtained according to a preset numbering rule, the next sample to be analyzed is numbered by the obtained mark number, the sample testing device 40 is started to detect after the next sample to be analyzed is in place, and the cycle is performed until an instruction of editing the mark number of the sample, which is input by a user, is received. The preset numbering rules may be set according to the user's requirements, for example, starting from 1, numbering is performed in a sequential increasing manner with each time 1 is added, so-called serial numbering.

After a user, such as a checking doctor, starts the analyzer for the first time on the same day, the analyzer numbers the analyzed samples by serial numbers, i.e. the mark numbers of the samples are 1,2,3, … … and N, and after the doctor goes to work, the continuous testing work is interrupted and the other doctors take over the work. Other doctors see the mark number of the sample which is currently analyzed by the analyzer, and usually take the mark number as a basis, the next mark number is input as a starting mark number, for example, the mark number of the sample which is analyzed in the current analyzer is 8, and then the doctor usually inputs 9 as the mark number of the next sample, and the analyzer takes 9 as the starting mark number to sequentially and incrementally number the subsequent samples. However, the first physician usually retests the abnormal sample before going to work, sample number 8 may be the retested sample mark number, and in practice the last numbered (i.e. the largest mark number) sample may be several tens or hundreds of times, so that the following mark number is easily misplaced by the working physician according to the conventional thinking operation. When the analyzer of the invention is adopted, after a doctor inputs the mark number of the sample, if the mark number is found to be the mark number repeated on the same day, the doctor can find that the mark number input by the doctor is abnormal or is edited by other inspection doctors before, and the correctness of the mark number of the current initial sample needs to be checked again. The invention can effectively help doctors to find abnormal initial mark numbers in advance and prevent the risk of wrong sample information.

After the man-machine interaction device 50 prompts the mark number input by the user to be the repeated mark number, the instruction acquisition module also receives the mark number input again by the user through the man-machine interaction device 50 so that the judgment module can judge the next round.

In the second embodiment, based on the first embodiment, the judging module is further configured to judge whether the flag number input by the user belongs to a preset number type. The number type may be a number or a letter, or a combination of a number and a letter.

The prompting module is further configured to prompt, through the man-machine interaction device 50, that the sign number input by the user is illegal when the sign number input by the user is not of a preset number type. For example, the user is prompted by displaying a highlighted text, a voice prompt, or a light emission of an indicator light on the display interface.

And the numbering module takes the mark number input by the user as the initial mark number when the mark number input by the user is not the mark number of the analyzed sample and the mark number input by the user belongs to the preset numbering type, and sequentially numbers the samples to be analyzed according to the preset numbering rule, so that the samples are provided with a mark number after being analyzed. In this embodiment, the numbering rules are: for each sample numbered, the flag is incremented by 1.

In the third embodiment, based on the first embodiment, the prompting module is further configured to predict a flag or a flag interval according to the flag of the analyzed sample and a preset numbering rule in response to an instruction of editing the flag of the sample input by the user, and display the predicted flag or flag interval for reference by the user through the display interface of the man-machine interaction device 50. For example, the numbering convention is: for each sample numbered, the flag is incremented by 1. After the user inputs an instruction for editing the mark number of the sample, the prompt module searches the storage device 10 for the maximum mark number of the sample analyzed on the same day, adds 1 to the maximum mark number to obtain a predicted mark number, and provides the predicted mark number for the user to refer to. Therefore, the work of the user can be saved, and the user is prevented from inputting wrong mark numbers.

The numbering module takes the mark number input by a user as an initial mark number to number the current sample to be analyzed, and starts the sample testing device 40 to detect the sample to be analyzed; after the sample suction of the current sample is finished, obtaining the mark number of the next sample to be analyzed according to a preset numbering rule, judging whether the obtained mark number is the mark number of the analyzed sample, if yes, prompting a user to repeat the mark number through a prompting module, if not, numbering the next sample to be analyzed by using the obtained mark number, starting a sample testing device 40 to detect after the next sample to be analyzed is in place, and circulating until receiving an instruction of editing the mark number of the sample input by the user. Thus, the analyzed samples are in one-to-one correspondence with the mark numbers and are unique.

After the man-machine interaction device 50 prompts the mark number input by the user to be the repeated mark number, the instruction acquisition module further receives an instruction for confirming the use of the mark number through the man-machine interaction device 50. And the numbering module is used for sequentially numbering samples to be analyzed according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed, wherein the mark number is repeated after the instruction acquisition module receives an instruction for confirming the use of the mark number, but the mark number input by a user is still used as an initial mark number. This can be used for sample retesting, e.g., sample number 8 is abnormally retested, and if an incremental numbering rule is used, the number for retesting is 9, which is not identical to the sample. Therefore, the user inputs the mark number 8, and the number is used for realizing retesting although the prompt is repeated, and the number of the subsequent sample is not influenced.

Based on the analyzer provided in the foregoing embodiment, the present invention further provides a sample numbering method, as shown in fig. 3, including:

Step 71, receiving an instruction of editing a mark number of a sample, which is input by a user;

step 72, responding to the instruction and receiving a mark number input by a user; the mark number is used for numbering the samples;

step 81, judging whether the mark number is the mark number of the analyzed sample, if yes, entering step 82; otherwise, go to step 83;

Step 82, prompting the user to input a repeated mark number; then returning to step 71, namely receiving the sign number input again by the user;

and 83, taking the mark number input by the user as an initial mark number, and sequentially numbering samples to be analyzed according to a preset numbering rule, so that the samples are provided with a mark number after being analyzed. The numbering rules may be set according to the user's needs, for example, the numbering rules are: for each sample numbered, the flag is incremented by 1.

Further, as shown in fig. 4, step 83 includes:

Step 831, taking the mark number input by the user as the initial mark number to number the current sample to be analyzed, and starting the analysis of the sample to be analyzed;

And 832, after the sample suction of the current sample is completed, obtaining the mark number of the next sample to be analyzed according to a preset numbering rule, numbering the next sample to be analyzed by using the obtained mark number, and starting the analysis of the sample to be analyzed until receiving an instruction of editing the mark number of the sample input by a user. Specifically, step 832 includes: after the sample suction of the current sample is completed, obtaining the mark number of the next sample to be analyzed according to a preset numbering rule, judging whether the obtained mark number is the mark number of the analyzed sample, if so, prompting the user that the mark number is repeated; otherwise, numbering the next sample to be analyzed by using the obtained mark number, and starting the analysis of the sample to be analyzed until receiving an instruction of editing the mark number of the sample input by a user.

In a specific embodiment, before step 83, steps 91 and 92 are further included, in the embodiment shown in fig. 5, step 81 is to determine whether the sign input by the user is the sign of the analyzed sample, if not, step 91 is entered;

step 91, judging whether the mark number input by the user belongs to a preset number type, if so, entering step 83; otherwise go to step 92;

Step 92, prompting that the mark number input by the user is illegal.

In another embodiment, steps 91 and 92 are further included before step 83, and step 91 is entered after step 72 in the embodiment shown in fig. 6: judging whether the mark number input by the user belongs to a preset number type, if so, entering a step 81; otherwise, step 92 is entered.

Step 92, prompting that the mark number input by the user is illegal.

Further, the method may further comprise the steps of: and responding to an instruction input by a user for editing the mark number of the sample, predicting a mark number or a mark number interval according to the mark number of the analyzed sample and a preset numbering rule, and displaying the predicted mark number or mark number interval through a display interface for reference by the user.

Of course, after step 82, it may further include: and receiving an instruction of confirming the use of the mark number by a user so as to retest the sample.

Since the specific process, implementation and effect of the sample numbering method are described in detail in the above-mentioned embodiments of the analyzer, they are not described in detail herein.

Those skilled in the art will appreciate that all or part of the functions of the various methods in the above embodiments may be implemented by hardware, or may be implemented by a computer program. When all or part of the functions in the above embodiments are implemented by means of a computer program, the program may be stored in a computer readable storage medium, and the storage medium may include: read-only memory, random access memory, magnetic disk, optical disk, hard disk, etc., and the program is executed by a computer to realize the above-mentioned functions. For example, the program is stored in the memory of the device, and when the program in the memory is executed by the processor, all or part of the functions described above can be realized. In addition, when all or part of the functions in the above embodiments are implemented by means of a computer program, the program may be stored in a storage medium such as a server, another computer, a magnetic disk, an optical disk, a flash disk, or a removable hard disk, and the program in the above embodiments may be implemented by downloading or copying the program into a memory of a local device or updating a version of a system of the local device, and when the program in the memory is executed by a processor.

The foregoing description of the invention has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the invention pertains, based on the idea of the invention.

Claims (9)

1. A method for numbering samples of an analyzer, comprising the steps of:

responding to an instruction of editing the mark number of the sample input by a user, and receiving the mark number input by the user; the mark number is used for numbering the samples;

judging whether the mark number is the mark number of the analyzed sample;

If the sample is not the mark number of the analyzed sample, taking the mark number input by the user as the initial mark number, and sequentially increasing the numbers of the samples to be analyzed according to a preset increasing number rule to ensure that the samples are provided with a unique mark number after being analyzed until receiving an instruction of editing the mark number of the sample, which is input by the user;

If yes, prompting a user to input a repeated mark number, receiving an instruction of confirming the use of the mark number by the user, taking the mark number input by the user as an initial mark number to the current sample to be analyzed, starting the analysis of the sample to be analyzed, obtaining the mark number of the next sample to be analyzed according to a preset incremental numbering rule after the sample suction of the current sample is completed, judging whether the obtained mark number is the mark number of the sample to be analyzed, and if yes, prompting the user to repeat the mark number.

2. The method of claim 1, wherein the step of taking the mark number input by the user as the initial mark number, sequentially increasing numbers of the samples to be analyzed according to a preset increasing number rule to make the samples have a mark number after being analyzed until receiving an instruction of editing the mark number of the samples input by the user, comprises:

Taking the mark number input by the user as the initial mark number to number the current sample to be analyzed, and starting the analysis of the sample to be analyzed;

After the sample suction of the current sample is completed, the mark number of the sample to be analyzed is obtained according to a preset incremental numbering rule, the obtained mark number is used for numbering the sample to be analyzed, and the analysis of the sample to be analyzed is started until an instruction of editing the mark number of the sample, which is input by a user, is received.

3. The method of claim 2, wherein prior to the step of numbering the current sample to be analyzed with the user-entered flag number as the starting flag number, further comprising: judging whether the mark number input by the user belongs to a preset number type, if so, numbering the current sample to be analyzed by taking the mark number input by the user as a starting mark number.

4. The method of claim 3, wherein if the sign number entered by the user is not of a preset number type, prompting the user that the entered sign number is not legal.

5. The method of claim 1, wherein the incremental numbering rule is: for each sample numbered, the flag is incremented by 1.

6. The method as recited in claim 1, further comprising: and responding to an instruction input by a user for editing the mark number of the sample, predicting a mark number or a mark number interval according to the mark number of the analyzed sample and a preset incremental numbering rule, and displaying the predicted mark number or mark number interval through a display interface for reference by the user.

7. The method of claim 2, wherein prior to the step of numbering the next sample to be analyzed with the resulting tag number, further comprising:

Judging whether the obtained mark number is the mark number of the analyzed sample, if so, prompting the user that the mark number is repeated.

8. An analyzer, comprising:

The sample testing device is used for analyzing a preset item of a sample and outputting an analysis result;

The man-machine interaction device is used for receiving the input and output visual information of a user;

a storage device for storing a program;

Processing means for implementing the method according to any one of claims 1-7 by executing a program.

9. A computer readable storage medium comprising a program executable by a processor to implement the method of any one of claims 1-7.