JP5350611B2 - Display method and sample analyzer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display method for displaying a particle distribution map of a measured sample and a reference particle distribution map in a comparable manner without reducing a display area for displaying data other than a particle distribution map, and to provide a sample analyzer. <P>SOLUTION: The sample analyzer is constituted so as to analyze a sample containing particles and includes a display part, a measuring means for measuring the sample, a distribution map preparing means for preparing the particle distribution map which shows the distribution of the particles contained in the sample on the basis of the measuring data obtained by the measuring means, a memory part for housing the reference particle distribution map and a display control means which displays the particle distribution map of the measured sample at a predetermined distribution map display position of the display part, reads the reference particle distribution map from the memory part corresponding to the display indication of the reference particle distribution map and displays the reference particle distribution map at the predetermined distribution map display position so as to compare the same with the particle distribution map of the measured sample. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a particle distribution map display method and a sample analyzer in a sample analyzer capable of analyzing a sample containing particles such as blood cells and urine cells.

  Conventionally, an analyzer for analyzing a sample containing particles is known (see, for example, Patent Document 1). In the sample analyzer described in Patent Document 1, parameters representing the characteristics of each particle such as red blood cells and white blood cells in a blood sample are detected electrically or optically, and a one-dimensional frequency distribution diagram is detected using the detected parameters. (Histogram) and a two-dimensional scattergram are created.

  The sample analyzer described in Patent Document 1 includes a display unit, and as shown in FIG. 9 of Patent Document 1, the display unit displays an analysis result obtained by analyzing blood sample measurement data. An analysis result display screen is displayed. This analysis result display screen shows the number of each particle such as red blood cells contained in the measured blood sample, and the particle distribution diagram (histogram or scattergram) created as described above. By displaying such an analysis result display screen, the user can know the number of each particle such as red blood cells contained in the measured blood sample and can visually recognize the particle distribution state in the particle distribution map. Can do.

JP 2006-17637 A

  By the way, since it is not easy for a user to evaluate whether the distribution state is abnormal or normal by looking at the particle distribution state in the particle distribution map, an index for evaluating the distribution state There is a need to display a reference particle distribution map on the display unit.

  However, in order to meet such needs, for example, when a particle distribution diagram showing a normal distribution state is displayed as a particle distribution diagram for reference side by side with the particle distribution diagram of the measured sample, FIG. Since the display area on the analysis result display screen as shown in FIG. 2 is limited, there is a problem that the display area for displaying information other than the particle distribution map is reduced. In addition, if the display of each arranged particle distribution map is made small in order to secure a display area for displaying information other than the particle distribution map, it is difficult to visually recognize the particle distribution state in the particle distribution map. become.

Therefore, the present invention provides a particle distribution diagram of a measured biological sample and a reference reference beforehand without reducing the display area for displaying information other than the particle distribution diagram on the analysis result display screen of the measured biological sample. a particle distribution diagram of a reference registered can be easily compared to Rukoto to provide a display method and a sample analyzing apparatus as.

Display method according to the first aspect of the present invention is a display method of the particle distribution diagram in the analysis capable sample analyzer biological sample containing particles, by measuring one of a biological sample containing particles, the biological while counting classifies particles contained in the sample, to create a particle distribution diagram showing a distribution of particles contained in the biological sample, the particle distribution diagram of the one of the biological sample in a predetermined distribution diagram display position A first display step of displaying an analysis result display screen on which a result of classifying and counting particles of the one biological sample is displayed in a predetermined measurement item display area, and a reference distribution map in accordance with the display instruction, the predetermined distribution diagram display position of the analysis result display screen, the first display in place of the particle distribution map displayed in step, the particles for reference registered in advance as a reference distribution And a second display step of displaying.

A sample analyzer according to a second aspect of the present invention is a sample analyzer capable of analyzing a biological sample containing particles, and acquires measurement data by measuring a display unit and one biological sample . Based on the measurement data, classify and count the particles contained in the biological sample, and create a particle distribution diagram indicating the distribution of particles contained in the sample based on the measurement data obtained by the measurement means. A distribution map creation means, a storage unit capable of storing a reference particle distribution map registered in advance for reference, and a particle distribution map of the one biological sample measured at a predetermined distribution map display position are displayed. And a display control means for displaying an analysis result display screen on which a result obtained by classifying and counting particles of the one biological sample in a predetermined measurement item display region is displayed on the display unit, Display control means , According to the display instruction of the reference distribution map, reads the particle distribution map which is registered in the reference from the storage unit, to said predetermined distribution diagram display position, the measured particle distribution of said one biological sample Instead of the figure, the read particle distribution map for reference is displayed.

According to the present invention, on the analysis result display screen of the measured biological sample , the user refers to the count result of the classified particles without reducing the display area for displaying information other than the particle distribution map. while, the particle distribution map for reference particle distribution map of the measured biological sample can be readily compared to Rukoto.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[overall structure]
The blood analyzer 1 according to this embodiment is an analyzer that analyzes blood of animals other than humans such as dogs, cats, cows, and horses. As shown in FIG. 1, the blood analyzer 1 is mainly composed of a measurement unit 2 and a data processing unit 3, and the measurement unit 2 performs a predetermined measurement on components contained in the blood, and this measurement data. Is received by the data processing unit 3 for data processing. The measurement unit 2 and the data processing unit 3 are connected by a data transmission cable 3a so that data communication with each other is possible.

[Measurement unit]
As shown in FIG. 2, a blood collection tube setting portion 2 a capable of setting a blood collection tube 20 containing blood is provided in the lower right part of the front of the measurement unit 2. The blood collection tube setting portion 2a is configured to open forward and push forward when the user presses a button switch 2b provided in the vicinity thereof, and the user can set the blood collection tube 20 in this state. It has become. After the blood collection tube 20 is set, when the user presses the button switch 2b again, the blood collection tube setting portion 2a moves rearward and closes.

  As shown in FIGS. 3 and 4, the blood collection tube setting portion 2a in which the blood collection tube 20 is set is accommodated in the measurement unit 2 as described above, and the blood collection tube 20 is positioned at a predetermined suction position. Inside the measurement unit 2 is provided a sample preparation section 4 having a pipette 21 for sucking blood, chambers 22 and 23 for mixing and preparing blood and a reagent, and the like. The pipette 21 is formed in a tubular shape extending in the vertical direction, and its tip is sharply pointed. The pipette 21 is connected to a syringe pump (not shown), can suck and discharge a predetermined amount of liquid by the operation of the syringe pump, and is connected to a moving mechanism, and is And can be moved in the front-rear direction. The blood collection tube 20 is sealed with a rubber cap 20a, and the cap 20a of the blood collection tube 20 set at the suction position is punctured by the sharp tip of the pipette 21, and the blood contained in the blood collection tube 20 is pipetted. 21 can suck a predetermined amount. Further, as shown in FIG. 4, chambers 22 and 23 are provided behind the blood collection tube setting portion 2a, and the pipette 21 in the state in which blood is sucked in this way is moved above the chambers 22 and 23 by the moving mechanism. And the blood is discharged into the chambers 22 and 23, whereby the blood is supplied to the chambers 22 and 23.

  As shown in FIG. 5, the measurement unit 2 includes a sample preparation unit 4, a WBC detection unit 5, an RBC / PLT detection unit 6, an HGB detection unit 7, a control unit 8, and a communication unit 9. Yes. The control unit 8 includes a CPU, a ROM, a RAM, and the like, and performs operation control of various components of the measurement unit 2. The communication unit 9 is an RS-232C interface and can exchange data with the data processing unit 3.

[Sample preparation section]
As shown in FIGS. 6 and 7, the sample preparation unit 4 is a fluid unit including a chamber, a plurality of electromagnetic valves, a diaphragm pump, and the like. The chamber 22 shown in FIG. 6 is used for preparation of a measurement sample used for measurement of red blood cells and platelets and measurement of hemoglobin. The chamber 22 is connected to a reagent container EPK containing the diluent shown in FIG. 7 via a fluid passage P6 such as a tube. The chamber 23 is used for preparing a measurement sample to be used for white blood cell measurement. The chamber 23 is connected to a reagent container FFD containing a hemolytic agent and a reagent container FFS containing a staining solution via fluid flow paths P1 and P2 such as tubes. The chamber 22 is connected to the RBC / PLT detector 6 via a fluid flow path P7 including a tube and an electromagnetic valve SV2. The chamber 23 is connected to the WBC detection unit 5 via a fluid flow path P3 including a tube and an electromagnetic valve SV4. The sample preparation unit 4 is provided with a sheath liquid chamber 24, and the sheath liquid chamber 24 is connected to the WBC detection unit 5 through a fluid flow path P4.

[WBC detector]
The WBC detection unit 5 is an optical flow cytometer, and can measure white blood cells by a flow cytometry method using a semiconductor laser. The WBC detection unit 5 includes a flow cell 51 that forms a liquid flow of the measurement sample. As shown in FIG. 8, the flow cell 51 is formed in a tubular shape with a material such as quartz, glass, and synthetic resin having translucency, and the inside thereof is a flow path through which the measurement sample and the sheath liquid flow. Yes. The flow cell 51 is provided with an orifice 51a whose internal space is narrowed narrower than other portions. Near the inlet of the orifice 51a of the flow cell 51 has a double tube structure, and the inner tube portion is a sample nozzle 51b. The sample nozzle 51b is connected to the fluid flow path P3 of the sample preparation unit 4, and a measurement sample is discharged from the sample nozzle 51b. The space outside the sample nozzle 51b is a flow path 51c through which the sheath liquid flows, and this flow path 51c is connected to the fluid flow path P4 described above. The sheath liquid supplied from the sheath liquid chamber 24 flows through the flow path 51c via the fluid flow path P4 and is introduced into the orifice 51a. As described above, the sheath liquid supplied to the flow cell 51 flows so as to surround the measurement sample discharged from the sample nozzle 51b. Then, the flow of the measurement sample is narrowed down by the orifice 51a, and particles such as white blood cells and red blood cells contained in the measurement sample are surrounded by the sheath liquid and pass through the orifice 51a one by one.

  As shown in FIG. 9, in the WBC detection unit 5, a semiconductor laser light source 52 is disposed so as to emit laser light toward the orifice 51 a of the flow cell 51. An irradiation lens system 53 including a plurality of lenses is disposed between the semiconductor laser light source 52 and the flow cell 51. By this irradiation lens system 53, the parallel beam emitted from the semiconductor laser light source is focused on the beam spot. Further, a beam stopper 54 a is provided on the optical axis extending linearly from the semiconductor laser light source 52 so as to face the irradiation lens system 53 with the flow cell 51 interposed therebetween, and direct light from the semiconductor laser light source 52 is provided. Is shielded by the beam stopper 54a. A photodiode 54 is disposed further downstream of the beam stopper 54a on the optical axis.

  When the measurement sample flows through the flow cell 51, scattered light and fluorescent light signals are generated by the laser light. Among these, the front signal light is irradiated toward the photodiode 54. Of the light traveling along the optical axis extending linearly from the semiconductor laser light source 52, the direct light of the semiconductor laser light source 52 is blocked by the beam stopper 54a, and the photodiode 54 travels substantially along the optical axis direction. Only scattered light (hereinafter referred to as forward scattered light) enters. Forward scattered light emitted from the flow cell 51 is photoelectrically converted by the photodiode 54, and an electric signal (hereinafter referred to as forward scattered light signal) generated thereby is amplified by the amplifier 54 b and output to the control unit 8. The forward scattered light signal reflects the size of the blood cell, and the control unit 8 processes the forward scattered light signal to obtain the size of the blood cell.

  A lateral condenser lens 55 is disposed on the side of the flow cell 51 and in a direction perpendicular to the optical axis extending linearly from the semiconductor laser light source 52 to the photodiode 54 and passes through the flow cell 51. Lateral light (light emitted in a direction intersecting the optical axis) generated when a blood cell is irradiated with a semiconductor laser is collected by the lateral condenser lens 55. A dichroic mirror 56 is provided on the downstream side of the side condenser lens 55, and the signal light transmitted from the side condenser lens 55 is divided into a scattered light component and a fluorescent component by the dichroic mirror 56. On the side of the dichroic mirror 56 (direction intersecting the optical axis direction connecting the side condenser lens 55 and the dichroic mirror 56), a photodiode 57 for receiving side scattered light is provided. An optical filter 58a and an avalanche photodiode 58 are provided on the downstream side of the optical axis. Then, the side scattered light component divided by the dichroic mirror 56 is photoelectrically converted by the photodiode 57, and an electric signal (hereinafter referred to as a side scattered light signal) generated thereby is amplified by the amplifier 57a. Is output. This side scattered light signal reflects the internal information (nucleus size, etc.) of the blood cell, and the control unit 8 processes the side scattered light signal to determine the size, etc. of the blood cell nucleus. To get. The side fluorescent component emitted from the dichroic mirror 56 is wavelength-selected by the optical filter 58a and then photoelectrically converted by the avalanche photodiode 58, and the electric signal (side fluorescent signal) generated thereby is amplified by the amplifier 58b. And output to the control unit 8. This side fluorescent signal reflects information relating to the degree of staining of blood cells, and by processing the side fluorescent signals, the staining properties of blood cells and the like are obtained.

[RBC / PLT detector]
The RBC / PLT detector 6 can measure the red blood cell count and the platelet count by the sheath flow DC detection method. The RBC detection unit 6 includes a flow cell, and a measurement sample is supplied from the chamber 22 described above to the flow cell. When measuring red blood cells and platelets, the chamber 22 prepares a measurement sample in which a diluent is mixed with blood. The measurement sample is supplied to the flow cell from the sample preparation unit 4 together with the sheath liquid, and a liquid flow is formed in the flow cell in which the measurement sample is surrounded by the sheath liquid. In addition, an aperture with electrodes is provided in the middle of the flow path in the flow cell, and the DC resistance in the aperture when each blood cell in the measurement sample passes through the aperture is detected, and this electric signal is controlled. The data is output to the unit 8. Since the DC resistance increases when a blood cell passes through the aperture, the electrical signal reflects the passage information of the blood cell of the aperture, and by processing the electrical signal, red blood cells and platelets are counted. It has become.

  When human blood is measured, red blood cells and platelets can be discriminated well using the RBC / PLT detection unit 6 which is an electric detection unit. However, when animal blood is measured, In some cases, the RBC / PLT detection unit 6 alone cannot satisfactorily distinguish red blood cells from platelets. Therefore, the blood analyzer 1 according to the present embodiment uses the RBC / PLT detection unit 6 that is an electrical detection unit and the WBC detection unit 5 that is an optical detection unit to measure red blood cells and platelets. It is configured to measure.

[HGB detector]
The HGB detector 7 can measure the amount of hemoglobin by the SLS hemoglobin method. The HGB detection unit 7 is provided with a cell for storing a diluted sample, and the sample is supplied from the chamber 22 to the cell. When measuring hemoglobin, the chamber 22 prepares a measurement sample in which a diluent and a hemolytic agent are mixed with blood. This hemolytic agent has the property of converting hemoglobin in blood into SLS-hemoglobin. In addition, a light emitting diode and a photodiode are disposed to face each other with a cell interposed therebetween, and light from the light emitting diode is received by the photodiode. The light emitting diode emits light having a wavelength with a high absorbance by SLS-hemoglobin, and the cell is made of a highly transparent plastic material. Thereby, in the photodiode, the transmitted light in which the light emission of the light emitting diode is absorbed only by the diluted sample is received. The photodiode is configured to output an electrical signal corresponding to the amount of received light (absorbance) to the control unit 8, and the control unit 8 compares this absorbance with the absorbance of only the diluted solution, Hemoglobin value is calculated.

  The control unit 8 receives electrical signals from the WBC detection unit 5, the RBC / PLT detection unit 6, and the HGB detection unit 7 as described above, and the size of the blood cell, the size of the blood cell nucleus, the staining property of the blood cell, Measurement data representing the red blood cell count, platelet count, hemoglobin value, etc. is transmitted to the data processing unit 3 via the communication unit 9.

[Data processing unit]
As shown in FIG. 10, the data processing unit 3 is composed of a computer mainly composed of a main body 301, a display 302, and an input device 303. The main body 301 mainly includes a CPU 301a, a ROM 301b, a RAM 301c, a hard disk 301d, a reading device 301e, an input / output interface 301f, an image output interface 301h, and a communication interface 301g. The hard disk 301d, the reading device 301e, the input / output interface 301f, the image output interface 301h, and the communication interface 301g are connected by a bus 301i so that data communication is possible.

  The CPU 301a can execute a computer program stored in the ROM 301b and a computer program loaded in the RAM 301c. The computer functions as the data processing unit 3 when the CPU 301a executes an application program 305a described later.

  The ROM 301b is configured by a mask ROM, PROM, EPROM, EEPROM, or the like, and stores a computer program executed by the CPU 301a, data used for the same, and the like.

  The RAM 301c is configured by SRAM, DRAM, or the like. The RAM 301c is used for reading computer programs recorded in the ROM 301b and the hard disk 301d. Further, when these computer programs are executed, they are used as a work area of the CPU 301a.

  The hard disk 301d is installed with various computer programs to be executed by the CPU 301a, such as an operating system and application programs, and data used for executing the computer programs. An application program 305a described later is also installed in the hard disk 301d.

  The reading device 301e is configured by a flexible disk drive, a CD-ROM drive, a DVD-ROM drive, or the like, and can read a computer program or data recorded on the portable recording medium 305. The portable recording medium 305 stores an application program 305a for causing the computer to realize a predetermined function. The computer as the data processing unit 3 reads the application program 305a from the portable recording medium 305, The application program 305a can be installed in the hard disk 301d.

  Note that the application program 305a is not only provided by the portable recording medium 305, but also from the external device communicatively connected to the data processing unit 3 by an electric communication line (whether wired or wireless). It can also be provided through a communication line. For example, the application program 305a may be stored in a hard disk of a server computer on the Internet, and the data processing unit 3 may access the server computer to download the computer program and install it on the hard disk 301d. Is possible.

  The hard disk 301d is installed with an operating system that provides a graphical user interface environment such as Windows (registered trademark) manufactured and sold by Microsoft Corporation. In the following description, it is assumed that the application program 305a according to the present embodiment operates on the operating system.

  The input / output interface 301f includes, for example, a serial interface such as USB, IEEE 1394, and RS-232C, a parallel interface such as SCSI, IDE, and IEEE 1284, and an analog interface including a D / A converter, an A / D converter, and the like. ing. An input device 303 including a keyboard and a mouse is connected to the input / output interface 301f, and the user can input data to the data processing unit 3 by using the input device 303.

  The image output interface 301h is connected to a display 302 constituted by an LCD, a CRT, or the like, and outputs a video signal corresponding to image data given from the CPU 301a to the display 302. The display 302 displays an image (screen) according to the input video signal.

  The communication interface 301g is, for example, an Ethernet (registered trademark) interface. The data processing unit 3 can transmit and receive data to and from the measurement unit 2 using a predetermined communication protocol through the communication interface 301g.

  The data processing unit 3 processes the measurement data received from the measurement unit 2 by executing the above-described application program 305a by the CPU 301a, and performs white blood cell count (WBC), red blood cell count (RBC), hemoglobin amount (HGB), hematocrit. The value (HCT), average red blood cell volume (MCV), average red blood cell pigment content (MCH), average red blood cell pigment concentration (MCHC), platelet count (PLT), etc. are calculated. Further, the data processing unit 3 can create various two-dimensional scattergrams and histograms (one-dimensional frequency distribution diagrams) using the measurement data received from the measurement unit 2.

  The data processing unit 3 can store a plurality of reference particle distribution maps (reference scattergrams and histograms) corresponding to the animal species to be analyzed by the blood analyzer 1 in the hard disk 301d in advance. It is. The reference particle distribution map is displayed on the display 302 so that it can be compared with the particle distribution map of the measured specimen, and serves as an indicator of whether the measured specimen is normal or abnormal. Is.

  Further, the user of the blood analyzer 1 can input the animal species of the specimen measured by the measurement unit 2 using the input device 303 of the data processing unit 3. The data processing unit 3 has a function for displaying a screen for the user to select an animal species (for example, dog, cat, horse, etc.) on the display 302 and an input signal for selecting the animal species, such as a keyboard / mouse. And a function of receiving from the input device 303.

[Processing by measurement unit and data processing unit]
Next, the flow of processing in the measurement unit 2 and the data processing unit 3 will be described with reference to FIG. First, when the power of the measurement unit 2 and the data processing unit 3 is turned on by a user's operation, initialization of each mechanism unit of the measurement unit 2 and initialization of a computer program and the like stored in the data processing unit 3 are performed. (Steps S2-1 and S3-1). Subsequently, the CPU 301a of the data processing unit 3 displays the menu screen shown in FIG. 12 on the display 302 via the image output interface 301h (step S3-2). As shown in FIG. 12, the menu screen is provided with a tool bar (icon display area) T, a view (function screen area) V, and the like.

  Next, the CPU 301a of the data processing unit 3 determines whether or not there is a manual dialog display instruction (step S3-3). Specifically, the CPU 301a clicks a “manual” button T1 provided on the menu screen shown in FIG. 12 or the toolbar T of the analysis result screen shown in FIGS. 19, 28, and 29 described later. It is determined whether or not. When there is a manual dialog display instruction, the CPU 301a displays the manual dialog shown in FIG. 13 on the display 302 via the image output interface 301h (step S3-4).

  After displaying the manual dialog shown in FIG. 13, the CPU 301a determines whether or not the input of the sample number by the user and the selection of the species of the sample to be measured have been accepted (step S3-5). In the manual dialog, the CPU 301a can accept the input of the sample number and the selection of the species of the sample to be measured by the user. The manual dialog is provided with a specimen number input area 43, an animal species switching button 44, and animal species selection icons 45a to 45d. The user can input the sample number of the sample to be measured into the sample number input area 43 using the keyboard. Dogs are assigned to the animal species selection icon 45a in the manual dialog, cats to 45b, cattle to 45c, and horses to 45d. The icons indicate the assigned animal species. If there are animal species to be measured in these four icons, the user can select the animal species as a measurement subject (measurement animal species) by clicking on the icon of the animal species using a mouse. At this time, only the icon selected for the measurement animal species is displayed in color, and the other icons are displayed in black and white. Therefore, the user can easily confirm which measurement animal species is selected. Further, when setting an animal species other than these four animal species as the measurement animal species, the user clicks the animal species switching button 44 using the mouse. When the animal species switching button 44 is clicked, a pull-down menu (not shown) for selecting a measurement animal species is displayed. When one of the animal species buttons displayed in the pull-down menu is clicked, the CPU 301a of the data processing unit 3 accepts the animal species assigned to the clicked button as a measurement animal species. The specimen number and the information on the selected animal species input as described above are stored in the RAM 301c. When the CPU 301a receives the input of the sample number and the selection of the species of the sample to be measured, the CPU 301a proceeds to the process of step S3-6. In addition, when the input of the specimen number and the selection of the animal species from the user are not accepted (that is, when there is no instruction to display the manual dialog in Step S3-3, or the input of the specimen number and the animal species in Step S3-5) CPU 301a proceeds to the process of step S3-6, and in step S3-7, in accordance with the animal species (the dog in this embodiment) set in advance as a default in step S3-7. Data processing is executed under the analysis conditions. In this case, the CPU 301a assigns the sample number to the sample to be measured based on the rule set by default. Hereinafter, a case where a cat is selected by the user as the animal species of the specimen to be measured will be described.

  On the other hand, the control unit 8 of the measurement unit 2 determines whether or not a measurement start button (not shown) provided in the measurement unit 2 has been pressed (step S2-2).

  When the measurement start button is pressed, the control unit 8 determines a measurement sample for red blood cell and platelet measurement (hereinafter referred to as “RBC / PLT measurement sample”), a measurement sample for white blood cell measurement (hereinafter referred to as “WBC measurement”). And a measurement sample for hemoglobin measurement (hereinafter referred to as “HGB measurement sample”) is prepared by the sample preparation unit 4 (step S2-3). If the measurement start button is not pressed, the control unit 8 proceeds to the process of step S2-6.

  Subsequently, the measurement unit 2 performs measurement of the RBC / PLT measurement sample, measurement of the WBC measurement sample, and measurement of the HGB measurement sample (step S2-4). In the present embodiment, a part of the RBC / PLT measurement sample is measured by the RBC / PLT detection unit 6 and the other part of the RBC / PLT measurement sample is measured by the WBC detection unit 5. The WBC measurement sample is measured by the WBC detection unit 5, and the HGB measurement sample is measured by the HGB detection unit 7.

  Next, the control unit 8 of the measurement unit 2 transmits measurement data to the CPU 301a via the communication unit 9 and the communication interface 301g of the data processing unit 3 (step S2-5).

  On the other hand, the CPU 301a of the data processing unit 3 determines whether or not measurement data has been received from the control unit 8 of the measurement unit 2 (step S3-6), and receives the measurement data from the control unit 8 if received. Based on the measured data, classification / counting processing of particles contained in the measurement sample is executed (step S3-7). When the measurement data is not received, the CPU 301a proceeds to the process of step S3-12.

  In the particle classification / counting process, the CPU 301a of the data processing unit 3 creates the histogram shown in FIGS. 14 and 15 based on the measurement data of the RBC / PLT measurement sample measured by the RBC / PLT detection unit 6. The histogram shown in FIG. 14 is an RBC histogram drawn using the forward scattered light intensity in the X-axis direction and the number of particles in the Y-axis direction. A line L shown in this histogram discriminates red blood cells and platelets, and particles distributed in a region between the lines L and M are discriminated as red blood cells. FIG. 15 is a PLT histogram showing a region near the line L in the histogram of FIG. 14, and particles distributed in the region between the line N and the line L are discriminated as platelets. Since the positions of these lines L, M, and N differ depending on each animal species, the CPU 301a changes the positions of the lines L, M, and N according to the animal species accepted in step S3-5. The RBC histogram in FIG. 14 and the PLT histogram in FIG. 15 are examples of analysis results displayed on the display 302 in step S901 in FIG.

  In the blood analyzer 1 of the present embodiment, the RBC / PLT measurement sample is measured not only by the RBC / PLT detection unit 6 that is an electrical detection unit but also by the WBC detection unit 5 that is an optical detection unit. The The CPU 301a of the data processing unit 3 creates a scattergram shown in FIG. 16 based on the measurement data of the RBC / PLT measurement sample measured by the WBC detection unit 5. The scattergram shown in FIG. 16 is a PLT-O scattergram drawn using the side scattered light intensity in the X-axis direction and the forward scattered light intensity in the Y-axis direction, and classifies red blood cells and platelets ( Because red blood cells and platelets have different internal information on blood cells, they can be distinguished even if they have the same size). Based on this scattergram, the CPU 301a calculates the ratio between the number of red blood cells and the number of platelets. Using the calculated ratio, the CPU 301a calculates the ratio of red blood cells and platelets acquired based on the measurement data obtained in the RBC / PLT detection unit 6. The total number of particles is distributed to each blood cell, and the number of red blood cells and platelets is calculated. In addition, since the conditions for classifying red blood cells and platelets in the PLT-O scattergram differ depending on each animal species, the CPU 301a determines in the PLT-O scattergram according to the animal species accepted in step S3-5. Change the above conditions. The calculated number of red blood cells and platelets and the PLT-O scattergram of FIG. 16 are examples of analysis results displayed on the display 302 in step S901 of FIG.

  Further, the CPU 301a of the data processing unit 3 creates a two-dimensional scattergram shown in FIG. 17 based on the measurement data of the WBC measurement sample measured by the WBC detection unit 5. The scattergram shown in FIG. 17 is a DIFF scattergram drawn using the side scattered light intensity in the X-axis direction and the side fluorescence intensity in the Y-axis direction. On this scattergram, the CPU 301a classifies particles contained in the measurement sample into a red blood cell ghost cluster, a lymphocyte cluster, a monocyte cluster, an eosinophil cluster, and a neutrophil cluster. Then, the number of particles of each measurement item (lymphocyte, monocyte, eosinophil, neutrophil) of white blood cells is obtained by counting the particles of each cluster. The total white blood cell count is obtained by summing the number of particles in each cluster other than the cluster of red blood cell ghosts. Since conditions for classifying white blood cells in the DIFF scattergram differ depending on each animal species, the CPU 301a changes the above conditions in the DIFF scattergram according to the animal species accepted in step S3-5. Note that the acquired number of particles and the DIFF scattergram shown in FIG. 17 are examples of analysis results displayed on the display 302 in step S901 in FIG.

  The CPU 301a stores the analysis result acquired as described above in the hard disk 301d (step S3-8).

  Next, the CPU 301a displays the analysis result stored in the hard disk 301d on the display 302 via the image output interface 301h (step S3-9). Below, with reference to FIG. 18, the display process of the analysis result by CPU301a is demonstrated.

  First, the CPU 301a reads the analysis result stored in the hard disk 301d to the RAM 301c, and displays the analysis result screen shown in FIG. 19 on the display 302 via the image output interface 301h (step S901). The analysis result screen shown in FIG. 19 includes a menu bar 40, a tool bar T, a specimen information area 41, a view V, and the like. The view V includes a measurement item display area V1 and a distribution chart display area V2. The measurement item display area V1 displays the white blood cell count, red blood cell count, and the like acquired by the CPU 301a, and displays a distribution map display. In the region V2, an RBC histogram, a PLT histogram, a DIFF scattergram, and a PLT-O scattergram created by the CPU 301a are displayed. In the following, as shown in the specimen information area 41 of FIG. 19, a case will be described in which an analysis result obtained by analyzing cat blood measurement data is displayed.

  Next, the CPU 301a determines whether or not a right click has been performed on any particle distribution map in the distribution map display area V2 (step S902). As shown in FIG. 20, a right-click menu is displayed on the display 302 via the image output interface 301h (step S903). If the right click is not performed on any particle distribution map, the CPU 301a proceeds to the process of step S913. In addition, which particle distribution map is right-clicked is stored in the RAM 301c. In the following, a case where the right click is performed on the DIFF scattergram in the distribution map display area V2 will be described.

  After displaying the right click menu in the process of step S903, the CPU 301a determines whether or not the “reference particle distribution map” command provided in the right click menu is clicked (step S904). When the “Figure” command is clicked, as shown in FIG. 20, a hierarchical menu provided with a “Display” command and a “Change Setting” command is displayed on the display 302 via the image output interface 301h ( Step S905). If the “reference particle distribution map” command in the right-click menu is not clicked, the CPU 301a proceeds to the process of step S913.

  After displaying the hierarchical menu shown in FIG. 20, the CPU 301a determines which one of the “display” command and the “change setting” command in the hierarchical menu is clicked (step S906), and when the “display” command is clicked. The predetermined reference particle distribution map is read from the hard disk 301d to the RAM 301c (step S907), and the read reference particle distribution map is displayed on the display 302 by a predetermined display method via the image output interface 301h. (Step S908). Here, the reference particle distribution map is a particle distribution map for reference in step S914 in FIG. 18 and step S116 in FIG. 27, which will be described later, among the particle distribution maps of other specimens measured in the past. It is a registered one. The predetermined reference particle distribution map displayed on the display 302 in step S908 and the predetermined display method for displaying the reference particle distribution map are set in advance by default.

  When the “change setting” command is clicked in step S906, the CPU 301a displays a display setting dialog shown in FIGS. 21 and 22 for changing the display setting of the reference particle distribution map on the display 302 (step 302). S909). As described above, the reference particle distribution map displayed in step S908 and the display method thereof are set in advance by default. However, the user uses this display setting dialog to set only the default display process using the default. The display setting of the reference particle distribution map can be changed. As shown in FIGS. 21 and 22, the display setting dialog includes a “reference” tab A and a “display method” tab B, and a display area C for displaying the setting contents. As shown in FIG. 21, when the “Reference” tab A is selected, in the display area C, among the reference particle distribution maps stored in the hard disk 301d, the species of the measured specimen and the processing in step S902 are performed. A plurality of reference particle distribution maps corresponding to the particle distribution map determined to have been right-clicked are displayed in a list. Therefore, a plurality of reference particle distribution diagrams corresponding to the DIFF scattergram of cat blood are displayed in a list in the display area C shown in FIG. The user can set the reference particle distribution map displayed on the display 302 by selecting any of the reference particle distribution maps from the list-displayed reference particle distribution maps. On the other hand, when the “display method” tab B is selected in the display setting dialog, as shown in FIG. 22, each item (“switch” and “transparency change” of the display method of the reference particle distribution map is displayed in the display area C. ”And“ overlapping ”) and check boxes corresponding to each item are displayed. The user can select a reference particle distribution map display method by clicking one check box. These display methods will be described later.

  After displaying the display setting dialog in step S909, the CPU 301a determines whether or not a display setting change instruction for the reference particle distribution map is received in the display setting dialog (step S910), and receives a display setting change instruction. If there is a change, the display setting of the reference particle distribution map is changed (step S911). When the display setting change is not received, the CPU 301a proceeds to the process of step S913.

  After changing the display setting of the reference particle distribution map in step S911, the CPU 301a reads the reference particle distribution map from the hard disk 301d based on the changed display setting (step S912), and the read reference particles are read. The distribution map is displayed on the display 302 (step S908).

  At this time, when “switching” is set as the display method of the reference particle distribution map, the DIFF scattergram of the measured specimen is displayed at the display position of the DIFF scattergram on the analysis result screen shown in FIG. As shown in FIG. 23, the DIFF scattergram for reference is automatically switched and displayed every predetermined time (in this embodiment, about every 1 second) (the character “Ref.” Is displayed). The displayed figure is a DIFF scattergram for reference). More specifically, the DIFF scattergram of the measured specimen displayed on the analysis result screen once disappears from the screen, and at the same time, the DIFF scattergram for reference is displayed as the DIFF scattergram of the measured specimen. It is displayed at the same position as it was. After about 1 second, the DIFF scattergram for reference disappears from the screen, and at the same time, the DIFF scattergram of the measured specimen is displayed at the same position as the position where the DIFF scattergram for reference is displayed. Then, after about 1 second again, the DIFF scattergram of the measured specimen disappears from the screen, and at the same time, the reference DIFF scattergram is displayed. By automatically repeating such processing, two DIFF scattergrams are alternately switched and displayed at the same display position. Since the measured particle distribution map of the specimen and the reference particle distribution map are alternately switched and displayed, the user can easily compare the two particle distribution maps. Therefore, for example, when the blood particle distribution map that seems to be normal is switched as the reference particle distribution map, whether or not the measured specimen is abnormal using the displayed reference particle distribution map as an index Can be evaluated at a glance. In addition, the particle distribution map of the measured specimen and the reference particle distribution map are alternately switched and displayed at the same display position, so that two particle distribution maps are simply displayed in parallel. It is possible to more easily grasp the difference in particle distribution state between the two particle distribution diagrams. Since the distribution of particles in the scattergram varies depending on the blood sample, it is possible to easily grasp subtle differences in the distribution of particles on the scattergram by alternately displaying the scattergram. Further, the display area for displaying the two particle distribution maps can be reduced as compared with the case where the two particle distribution maps are displayed side by side. Therefore, it is possible to display more information regarding the analysis result on the analysis result screen. Moreover, since the switching operation is automatically performed, it is possible to save the user from having to perform the switching operation. In addition, since the letters “Ref.” Are displayed in the reference particle distribution map, it is possible to easily distinguish between the measured particle distribution map of the specimen and the reference particle distribution map.

  Next, a case where “transparency change” and “superposition” are set as the display method of the reference particle distribution map will be described. For convenience of explanation, a case where a reference particle distribution map corresponding to the RBC histogram of cat blood is displayed will be described here.

  First, when “transparency change” is set as the display method of the reference particle distribution map, as shown in FIG. 24, the measured RBC histogram of the specimen and the reference RBC histogram (“Ref.” And a control bar 42 on the right side. The control bar 42 has a function of changing the transparency of the distribution curve in the reference RBC histogram. When the handle 42a of the control bar 42 is positioned at the bottom of the control bar 42, the reference RBC The transparency of the distribution curve of the histogram is 100%, and the distribution curve is not displayed. Then, when the user drags the handle 42a upward, the transparency of the distribution curve of the reference RBC histogram is lowered, and the distribution curve is gradually displayed. On the other hand, when the user drags the handle 42a downward, the transparency of the distribution curve of the reference RBC histogram increases, and the distribution curve gradually disappears. Also by such a display method, the particle distribution maps of both can be easily compared. Further, the display area for displaying the two particle distribution maps can be reduced as compared with the case where the two particle distribution maps are displayed side by side. Therefore, it is possible to display more information regarding the analysis result on the analysis result screen.

  When “superposition” is set as the display method of the reference particle distribution map, as shown in FIG. 25, the RBC histogram of the measured specimen and the reference RBC histogram are displayed so as to overlap each other. Is done. At this time, the distribution curves in both RBC histograms are drawn and displayed in different colors. Therefore, the particle distribution diagrams of both can be easily compared. In addition, when the reference particle distribution map is displayed by “superposition”, the display area for displaying the two particle distribution maps can be reduced as compared with the case where the two particle distribution maps are displayed side by side. . Therefore, it is possible to display more information regarding the analysis result on the analysis result screen.

After displaying the reference particle distribution map in step S908, the CPU 301a determines whether there is an instruction to register the reference particle distribution map (step S913). Specifically, as shown in FIG. 26, when the “execution ( A )” button provided in the menu bar 40 of the analysis result screen is clicked, a command “reference distribution map registration ( R )” is provided. When a menu is displayed and the command “Register distribution map for reference ( R )” is selected, the type of particle distribution map (“RBC”, “PLT”, “DIFF”, “PLT-O”) is displayed. A hierarchical menu with commands is displayed. The CPU 301a determines that there is an instruction to register a reference particle distribution map when any of the commands indicating the types of particle distribution maps is clicked. If there is no instruction to register the reference particle distribution map, the CPU 301a returns the process. In the following, a case where the “PLT-O” command in the hierarchical menu shown in FIG. 26 is clicked will be described.

  When there is an instruction to register a reference particle distribution map, the CPU 301a executes a reference particle distribution map registration process (step S914). In the registration process of step S914, the CPU 301a uses the PLT-O scattergram displayed in the distribution map display area V2 of the analysis result screen as a reference particle distribution map corresponding to the PLT-O scattergram of cat blood as a hard disk. 301d is stored. At this time, for example, “Ref. K” or “Ref. 6” is input as the file name corresponding to the stored particle distribution map, and the file name, measurement date and time, and specimen number are included in the particle distribution together with the particle distribution map data. Corresponding to the data shown in FIG. When the registration process of the reference particle distribution map is completed, the CPU 301a returns the process.

  Next, the CPU 301a determines whether or not it has been instructed to display on the display 302 about a stored sample whose analysis has been completed in the past and the analysis result is stored in the hard disk 301d (step S3-10). Specifically, the CPU 301a determines whether or not an “Explorer” button T2 (see FIG. 19) provided on the toolbar T of the analysis result screen is clicked. When the “explore” button T2 is clicked, the CPU 301a executes a display process for the stored specimen (step S3-11). When the “Explore” button T2 is not clicked, the CPU 301a proceeds to the process of step S3-12.

  With reference to FIG. 27, the display processing of the stored specimen in step S3-11 will be described. First, the CPU 301a displays an explorer screen shown in FIG. 28, which is a list screen of stored samples, on the display 302 (step S111). As shown in FIG. 28, on this explorer screen, a plurality of samples specified by animal species, sample numbers, etc. are displayed in a list.

  Next, the CPU 301a determines whether selection of any sample from the list displayed on the explorer screen has been accepted (step S112). Specifically, the user double-clicks one of the samples in the list, or clicks one of the samples and clicks the “Browser” button T3 (see FIG. 28) on the toolbar. Thus, the CPU 301a determines that selection of any sample from the list has been received.

  When the selection of any sample is accepted in step S112, the CPU 301a reads the analysis result of the selected sample from the hard disk 301d to the RAM 301c (step S113), and reads the analysis via the image output interface 301h. The result is displayed on the display 302 (step S114). An example is shown in FIG. In step S112, if no sample is selected from the list, the CPU 301a returns the process.

  After displaying the analysis result of the stored sample on the display 302 in step S114, the CPU 301a determines whether or not there is an instruction to register the reference particle distribution map (step S115), and there is an instruction to register the reference particle distribution map. In this case, the particle distribution map displayed in the distribution map display area V2 is registered as a reference particle distribution map (step S116). Since the processing in step S115 and step S116 is the same as the processing in step S913 and step S914 described above, description thereof will be omitted. When the process in step S116 ends, the CPU 301a returns the process. As described above, in this embodiment, it is possible to register a particle distribution map of a sample that has been analyzed in the past as a reference particle distribution map of another sample. Therefore, various particle distribution maps can be registered as reference particle distribution maps as required by the user.

  Next, the CPU 301a determines whether or not the user has issued a shutdown instruction, specifically, whether or not the “Shutdown” icon S on the menu screen (see FIG. 12) has been double-clicked (step S3-12). When the “shutdown” icon S is double-clicked, a shutdown signal is transmitted to the control unit 8 via the communication interface 301g and the communication unit 9 of the measurement unit 2 (step S3-13). When the “menu” button T4 on the toolbar T of the analysis result screen shown in FIGS. 19, 28, and 29 is clicked, the menu screen shown in FIG. 12 is displayed.

  If there is no shutdown instruction from the user, the CPU 301a returns to the process of step S3-3.

  On the other hand, the control unit 8 of the measurement unit 2 determines whether or not a shutdown signal has been received from the CPU 301a of the data processing unit 3 (step S2-6). If the shutdown signal is received, the measurement unit 2 is shut down. Is executed (step S2-7). When the shutdown signal is not received from the CPU 301a, the control unit 8 returns to the process of step S2-2.

  As described above, according to the blood analyzer 1 of the present embodiment, the particle distribution diagram of the measured blood sample and the reference are used without reducing the display area for displaying the analysis result information other than the particle distribution diagram. Can be displayed in a comparable manner.

  Further, according to the blood analyzer 1 of the present embodiment, the particle distribution map of the specimen measured in the past can be freely registered as the reference particle distribution map. Therefore, for example, if a particle distribution map of blood of an animal measured one week ago is registered as a reference particle distribution map, the blood of the same animal is measured one week later and the analysis result is displayed. The particle distribution map obtained one week ago can be displayed as a reference particle distribution map. Thereby, the time-dependent change of the analysis result of the blood of the same animal can be confirmed.

  In the above-described embodiment, the blood analyzer for analyzing blood of animal species other than humans such as dogs and cats has been described as an example. However, the present invention is not limited to this, and blood analysis for analyzing human blood is used. You may apply to an apparatus.

  In the present embodiment, the blood analyzer for analyzing a blood sample has been described as an example, but the present invention is not limited thereto, and in addition to blood cells, biological particles such as urine cells, fine ceramic particles, You may apply to the sample analyzer which analyzes the sample containing powder particles, such as a pigment and cosmetic powder.

  In the present embodiment, a two-dimensional scattergram drawn using the side scattered light intensity in the X-axis direction and the side fluorescent light intensity or the forward scattered light intensity in the Y-axis direction is displayed. For example, a three-dimensional scattergram in which the number of blood cells is taken in the Z-axis direction may be displayed.

In the present embodiment, the display setting of the reference particle distribution map is set by default. In the display setting dialog displayed by right-clicking on the particle distribution map on the analysis result screen, the above-mentioned reference reference display by default is performed. Although an example in which the display setting of the particle distribution map is changed is shown, the present invention is not limited to this. For example, a “setting ( S )” button provided on the menu bar 40 of the analysis result screen is clicked. Accordingly, an operation for changing the display setting of the reference particle distribution map may be performed.

  Further, in the present embodiment, even when the display setting of the reference particle distribution map by default is changed by the user in the display setting dialog, in the next display processing, the default display setting before being changed by the user is set. However, the present invention is not limited to this, and when the display setting of the reference particle distribution map by default is changed by the user in the display setting dialog described above, the present invention is not limited to this. In the next display process, the reference particle distribution map may be displayed based on the display setting changed by the user.

  In this embodiment, the reference particle distribution map displayed on the display 302 and the display method thereof are preset by default. However, the present invention is not limited to this, and the reference particle distribution displayed on the display 302 is not limited thereto. Only the figure may be preset by default, and the display method may be set by the user every time the reference particle distribution map is displayed.

  Further, in the present embodiment, when the display setting of the reference particle distribution map is not changed in the above display setting dialog, the reference particle distribution map is displayed on the display 302 based on the default display setting. However, this default display setting may be customized by the user.

  In addition, in this embodiment, when the display method of the reference particle distribution map is set to “switching”, the switching speed of the particle distribution map cannot be changed, but the switching speed of the particle distribution map can be changed. Alternatively, the data processing unit 3 may be configured. If comprised in this way, a user's convenience can be improved more.

  Further, in this embodiment, when the display method of the reference particle distribution map is set to “switching”, the switching operation of the particle distribution map is automatically performed, but the present invention is not limited to this. Instead, for example, every time the user double-clicks on the particle distribution map, the particle distribution map switching operation may be performed.

  Further, in the present embodiment, when the display method of the reference particle distribution map is set to “switching”, the particle distribution map of the measured specimen and one reference particle distribution map are alternately switched. However, the present invention is not limited to this, and among the reference particle distribution maps stored in the hard disk 301d, the reference particle distribution map displayed on the display 302 has a priority from, for example, first place. It may be set up to the 5th place, and the reference particle distribution maps from the 1st place to the 5th place may be automatically switched and displayed sequentially. Further, every time the user double-clicks on the particle distribution map, the first to fifth reference particle distribution maps may be sequentially switched and displayed.

  In this embodiment, the particle distribution map of the measured blood sample disappears from the screen, and at the same time, the reference particle distribution map is displayed on the screen, so that the two particle distribution maps are alternately switched and displayed. However, the present invention is not limited to this, and the particle distribution map of a blood sample measured by using a morphing technique (a technique for expressing an image in which one image is smoothly transformed into another image) is gradually referred to. You may display so that it may switch to the particle distribution map for use. In this case, deformation of the particle distribution map by the morphing technique may be automatically performed, or the particle distribution map may be deformed by providing a control bar and dragging the handle of the control bar by the user.

  In this embodiment, the particle distribution map of the measured blood sample disappears from the screen, and at the same time, the reference particle distribution map is displayed on the screen, so that the two particle distribution maps are alternately switched and displayed. However, the present invention is not limited to this. As the particle distribution map of the measured blood sample gradually disappears from the screen, the reference particle distribution map gradually appears on the screen, and the reference particle distribution map gradually disappears from the screen. The particle distribution map of the blood sample measured as the time may gradually appear on the screen. Such switching may be performed automatically, or may be performed by providing a control bar and dragging the handle of the control bar by the user.

  Further, in the present embodiment, an RBC histogram and a DIFF scattergram are displayed in the distribution map display area V2 of the analysis result screen shown in FIG. 19, and these particle distribution maps are displayed alternately with the reference particle distribution map. However, the present invention is not limited to this. For example, the blood sample of the same subject is periodically measured, and the analysis results such as the number of red blood cells and DIFF scattergram are stored in the hard disk for each measurement. Create a graph showing the change in number over time, display the created graph on the analysis result screen, and every time an arbitrary point of the distribution curve shown on the graph is clicked with the mouse, A particle distribution map such as a DIFF scattergram acquired at the date and time may be switched and displayed in accordance with the click. As a result, not only can the change over time of the red blood cell count be grasped, but also a particle distribution map acquired at a certain date and time can be compared with a particle distribution map acquired at another date and time with a simple operation.

  In this embodiment, when the display method of the reference histogram is set to “change transparency”, the transparency of the distribution curve of the reference histogram changes by the user dragging the handle of the control bar. However, the present invention is not limited to this, and the transparency of the distribution curve may change automatically.

  In this embodiment, when the display method of the reference histogram is set to “transparency change”, the transparency of the distribution curve of the reference histogram is changed, but the histogram of the measured blood sample is changed. The transparency of the distribution curve may change. In addition, if the transparency of the measured blood sample histogram distribution curve increases, the transparency of the reference histogram distribution curve decreases accordingly, and the transparency of the measured blood sample histogram distribution curve decreases. For example, the transparency of the reference histogram distribution curve may be increased accordingly.

  In this embodiment, the reference histogram is displayed by “transparency change”. However, the reference scattergram may be displayed by “transparency change” without being limited to the histogram.

  Further, in the present embodiment, when the histogram of the measured blood sample and the reference histogram are displayed in an overlapping manner, the distribution curves of the two histograms are drawn with lines of the same thickness. For example, FIG. As shown, the distribution curve in the histogram of the measured blood sample may be drawn thicker than the distribution curve in the reference histogram. Thereby, two distribution curves can be distinguished more clearly. Further, the two distribution curves may be distinguished by drawing the distribution curve of the reference histogram with a broken line.

  Further, in the present embodiment, the reference particle distribution map is stored in the hard disk 301d of the data processing unit 3 by executing the registration process of the reference particle distribution map in step S914 in FIG. 18 and step S116 in FIG. However, the present invention is not limited to this. For example, the reference particle distribution map is read by a reading device 301e from a portable recording medium such as a CD-ROM in which the reference particle distribution map is stored. The plurality of read particle distribution maps are displayed on the display 302 via the image output interface 301h, and the particle distribution map selected by the user using a mouse or the like from the displayed plurality of particle distribution maps is registered. The received particle distribution map may be stored in the hard disk 301d. In addition, the reference particle distribution map may be downloaded to the hard disk 301d from an external device that is communicably connected to the data processing unit 3 via a communication network such as a LAN or the Internet.

  In the present embodiment, the PLT-O scattergram obtained by measuring cat blood in the registration process of the reference particle distribution map in step S914 in FIG. 18 and step S116 in FIG. The reference particle distribution map corresponding to the PLT-O scattergram is registered. However, the present invention is not limited to this, and the PLT-O scattergram obtained by measuring the blood of the cat is, for example, the blood of the dog. A reference particle distribution map corresponding to the PLT-O scattergram may be registered.

  In the present embodiment, the reference particle distribution map stored in the hard disk 301d of the data processing unit 3 is displayed on the display 302. However, the present invention is not limited to this, and for example, a reference particle distribution map is stored. The reference particle distribution map may be read from the portable recording medium such as a CD-ROM by the reading device 301e, and the read reference particle distribution map may be displayed on the display 302 without being stored in the hard disk 301d. In addition, a reference particle distribution map may be displayed on the display 302 from an external device connected to the data processing unit 3 through a communication network such as a LAN or the Internet via the communication network.

  In this embodiment, the blood analyzer 1 includes the measurement unit 2 and the data processing unit 3 that is separate from the measurement unit 2. However, both the measurement unit 2 and the data processing unit 3 are included in a single device. May be equipped with the function.

  In the present embodiment, the user inputs the sample number and selects the animal species using the mouse / keyboard or the like on the screen displayed on the display 302 before the measurement of the sample is started. However, for example, a barcode recorded with the animal species and specimen number is pasted on the blood collection tube, and before the measurement is started, the barcode reader reads the barcode pasted on the blood collection tube, A blood analyzer may be configured.

  In this embodiment, the specimen number is input and the animal type is selected before the measurement of the specimen is started. However, the present invention is not limited to this. For example, the user selects the wrong animal type. When the measurement data is processed, the sample number may be input and the animal species may be selected again after the measurement data is processed. In this case, it is preferable to perform the data processing of the measurement data again under the analysis conditions corresponding to the animal species selected later.

It is a front view which shows schematic structure of the blood analyzer which concerns on embodiment of this invention. It is a perspective view which shows the external appearance of a measurement unit. It is a perspective view which shows the internal structure of a measurement unit. It is a side view of the measurement unit shown in FIG. It is a block diagram which shows the structure of a measurement unit. It is a fluid circuit diagram which shows the structure of a sample preparation part. It is a fluid circuit diagram which shows the structure of a sample preparation part. It is a perspective view which shows the structure of a flow cell typically. It is a schematic plan view which shows the structure of a WBC detection part typically. It is a block diagram which shows the structure of a data processing unit. It is a flowchart which shows the flow of a process of a measurement unit and a data processing unit. It is a figure which shows a menu screen. It is a figure which shows a manual dialog. It is a RBC histogram. It is a PLT histogram. It is a PLT-O scattergram. It is a DIFF scattergram. It is a flowchart which shows the flow of a display process of an analysis result. It is a figure which shows an analysis result display screen. It is a figure which shows the right click menu displayed when right-clicking on the particle distribution map of the analysis result display screen shown in FIG. It is a figure which shows a display setting dialog. It is a figure which shows a display setting dialog. It is a figure for demonstrating the display method (switching display) of the particle distribution map for a reference. It is a figure for demonstrating the display method (transparency change) of the reference particle distribution map. It is a figure for demonstrating the display method (superposition) of the particle distribution map for a reference. It is a figure which shows the hierarchy menu for performing the registration instruction | indication of the particle distribution map for reference. It is a figure which shows the flow of a display process of the analysis result of another sample. It is a figure which shows an explorer screen. It is a figure which shows the analysis result display screen of another sample. It is a figure for demonstrating the modification of the display method of the particle distribution map for reference.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Blood analyzer 2 Measurement unit 3 Data processing unit 302 Display 303 Input device 301a CPU
301c RAM
301d Hard disk 301e Reading device 301f Input / output interface 301g Communication interface 301h Image output interface 5 WBC detection unit 6 RBC / PLT detection unit 7 HGB detection unit 8 Control unit 9 Communication unit

Claims (17)

A display method of a particle distribution map in a sample analyzer capable of analyzing a biological sample containing particles,
By measuring one biological sample containing particles, the particles contained in the biological sample are classified and counted, and a particle distribution diagram showing the distribution of particles contained in the biological sample is created and determined in advance. An analysis result display in which a particle distribution map of the one biological sample is displayed at a distribution map display position , and a result obtained by classifying and counting the particles of the one biological sample in a predetermined measurement item display area A first display step for displaying a screen ;
According to the display instruction of the reference distribution map, the predetermined distribution diagram display position of the analysis result display screen, instead of the particle distribution map displayed in the first display step, it is registered in advance as a reference And a second display step of displaying a reference particle distribution map . The second display step is executed by alternately switching and displaying a particle distribution map of a measured biological sample and a reference particle distribution map at the predetermined distribution map display position. How to display.   The display according to claim 1 or 2, wherein the switching between the particle distribution map of the measured biological sample and the reference particle distribution map is executed by gradually changing one particle distribution map to the other particle distribution map. Method. Switching between the particle distribution map of the measured biological sample and the reference particle distribution map is performed as one particle distribution map gradually disappears from the predetermined distribution map display position, and the other particle distribution map is determined in advance . 4. The display method according to claim 3, wherein the display method is executed by displaying the distribution map so as to appear gradually.   The display method according to claim 1, further comprising a step of storing the measured particle distribution map of the biological sample as a reference particle distribution map in the storage unit. A sample analyzer capable of analyzing a biological sample containing particles,
A display unit;
Measuring means for obtaining measurement data by measuring one biological sample, and classifying and counting particles contained in the biological sample based on the obtained measurement data ;
A distribution map creating means for creating a particle distribution map showing the distribution of particles contained in the biological sample based on the measurement data obtained by the measurement means;
A storage unit capable of storing a particle distribution map for reference registered in advance for reference;
Appears particle distribution diagram of a pre-determined on select distribution diagram display position said one biological sample, and were counted by classifying particles of the one of the biological sample in a predetermined measurement item display region was the result but and a display control means for displaying on the display unit an analysis result display screen displayed,
The display control means reads out the particle distribution map registered for reference from a storage unit in response to a display instruction for a reference distribution map, and measures the one measured at the predetermined distribution map display position. A sample analyzer for displaying a read particle distribution map for reference instead of a particle distribution map of a biological sample. 7. The sample analyzer according to claim 6, wherein the display control means alternately displays a particle distribution map of the measured biological sample and a reference particle distribution map at the predetermined distribution map display position.   8. The sample analyzer according to claim 7, wherein the display control means automatically performs a particle distribution map switching operation.   The display control means further includes a switching instruction receiving means for receiving a switching instruction of the particle distribution map, and performs a switching operation of the particle distribution map in accordance with the switching instruction received by the switching instruction receiving means. Sample analyzer. The storage unit can store a plurality of reference particle distribution maps,
The display control means reads a plurality of reference particle distribution maps from the storage unit, sequentially switches the plurality of reference distribution maps, and displays them at the predetermined distribution map display position. The sample analyzer according to item 1. 11. The display control unit according to claim 6, wherein one of the measured particle distribution map of the biological sample and the reference particle distribution map is gradually changed to the other particle distribution map. Sample analyzer. 12. The sample according to claim 11, wherein the display control means comprises distribution map changing means for changing one particle distribution map of the measured particle distribution map of the biological sample and the reference particle distribution map to the other particle distribution map. Analysis equipment. Display control means, as gradually disappear from the measured one distribution diagram display positions particle distribution diagram is the predetermined point of the particle distribution diagram for reference particle distribution map and of the biological sample, wherein the advance and the other particle distribution diagram The sample analyzer according to claim 11 or 12, wherein the sample analyzer is displayed so as to appear gradually at a determined distribution map display position. The sample analyzer according to any one of claims 6 to 13, further comprising registration means for storing the particle distribution map of the biological sample measured by the measurement means as a reference particle distribution map in the storage unit. The storage unit can store a plurality of reference particle distribution maps,
A distribution map selection receiving unit for selecting a reference particle distribution map displayed at the predetermined distribution map display position from the plurality of reference particle distribution maps stored in the storage unit. Item 15. The sample analyzer according to any one of Items 6 to 14. The sample analyzer according to any one of claims 6 to 15, wherein the particle distribution map is a scattergram created using at least two types of parameters representing characteristics of particles in a biological sample. The sample analyzer according to any one of claims 6 to 16, wherein the biological sample is a blood sample.

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