JP2013002937A - Automatic analyzer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an automatic analyzer which is capable of preventing erroneous measurement by detecting that a sample container is taken out before dispensing a sample, and notifying a detected result.SOLUTION: An automatic analyzer produces a mixture by dispensing a sample and a reagent corresponding to the sample from containers upon receiving a measuring instruction, measures components of the sample through pre-analysis of components of the mixture and comprises a first storage, a second storage, detection means and notification means. The first storage is formed to store the sample container therein and to take it out. The second storage is formed to store the reagent container therein and to take it out. The detection means detects whether or not the sample container or the reagent container is taken out of the first storage or the second storage before the sample or the reagent is dispensed. The notification means notifies a detected result.

Description

  Embodiments described herein relate generally to an automatic analyzer that generates a mixed solution using a sample and a reagent and analyzes components of the mixed solution.

  In a conventional automatic analyzer, a sample is put in a sample container and held by a disk sampler or a rack sampler. The reagent is put in a reagent container and held in a reagent store. Identification information (for example, a barcode) for identifying the sample is attached to the sample container. Also, identification information for identifying the reagent is attached to the reagent container. In the following description, a sample and a reagent corresponding to the sample are referred to as “samples”, a sample container and a reagent container are simply referred to as “containers”, and a disk sampler, a rack sampler, or a reagent container is referred to as a “container”. There is a case.

  When the container is placed in the storage, the identification information is read. In response to the measurement instruction, each container moves to the dispensing position. A sample and a reagent are dispensed from each container into a reaction container, and the sample and the reagent react in the reaction container. By analyzing this mixed solution, the components of the sample are measured.

  There is a barcode reader that acquires information related to a sample by reading a barcode attached to a sample container (for example, Patent Document 1).

JP-A-8-240594

  However, in a conventional automatic analyzer, if an operator inadvertently replaces a container with another container before receiving a measurement instruction and dispensing a sample or the like from the container, an erroneous measurement is performed. There was a problem.

  The embodiment is made in order to solve the above-mentioned problems, and it is detected that the container has been taken out before dispensing a sample and the like, and the detection result is notified to prevent erroneous measurement. It is an object of the present invention to provide an automatic analyzer that can be used.

  The automatic analyzer of the embodiment receives a measurement instruction, generates a mixed solution by dispensing a sample and a reagent corresponding to the sample from each container, and measures a component of the sample by subanalysis of the components of the mixed solution. , First storage, second storage, detection means, and notification means. The first storage is formed so that the sample container can be taken in and out. The second storage is formed so that the reagent container can be taken in and out. The detection means detects whether the sample container or the reagent container has been taken out from the first container or the second container before the sample or the reagent is dispensed. The notification means notifies the detected result.

The block diagram which shows the structure of the automatic analyzer which concerns on 1st Embodiment. Sectional drawing of the sample warehouse made into a cross section along a central axis. The top view of the sample store | warehouse | chamber which removed the cover member etc. and showed the baseplate. The partial expanded sectional view of FIG. The figure which shows the installation log | history of a sample container. The figure which shows the installation log | history of a sample container. The flowchart which shows a series of operation | movement of an automatic analyzer. The flowchart which shows the operation | movement until it is judged whether dispensing etc. are continued after taking out of a container. The flowchart which shows the taking-out detection of a container. The flowchart which shows the aspect of alerting | reporting according to the time which detected taking-out of the container. The flowchart which shows judgment of whether dispensing etc. are continued based on the aspect of alerting | reporting. The partial expanded sectional view of the sample storehouse concerning 2nd Embodiment. The figure which shows the modification of an interlocking member.

[First Embodiment]
Embodiments of this automatic analyzer will be described with reference to the drawings.
The automatic analyzer is an apparatus that analyzes chemical components contained in a sample by dispensing a sample and a reagent and analyzing the reaction of the mixed solution. After dispensing a sample such as blood or urine and a reagent into the reaction tube and reacting them, the concentration or activity of the sample component or enzyme is measured by optically measuring the color change caused by the reaction.

  FIG. 1 is a block diagram showing the configuration of the automatic analyzer. As shown in FIG. 1, the automatic analyzer includes an analysis unit 1, a data processing unit 2, a drive unit 3, a user interface 4, a detection unit 5, a reading unit 6, a control unit 7, and a storage unit 8.

  The analysis unit 1 dispenses a sample and a reagent, analyzes the reaction of the mixed solution, and outputs measurement result data. In the following description, sample dispensing and reagent dispensing may be simply referred to as “dispensing”. Further, the sample container 11 and the reagent container 21 may be simply referred to as “containers”.

  The data processing unit 2 performs processing on the measurement result data output from the analysis unit 1 to generate inspection line data and analysis data, and outputs the inspection line data and analysis data to a monitor or printer provided.

  The driving unit 3 includes a motor, a gear, and the like, and drives each unit of the analysis unit 1 by generating a driving force and transmitting it to each unit of the analysis unit 1.

  The user interface 4 includes input means 43, display control means 41, and display means 42. An example of the input unit 43 is a pointing device such as a mouse, a trackball, a touch panel, a touch pad, a joystick, and a joypad. An example of the display means 42 is a monitor. The display control unit 41 receives an operation from the input unit 43, specifies a display area displayed on the display unit 42, and outputs an instruction corresponding to the specified display area to the control unit 7. Further, the display control unit 41 causes the display unit 42 to display the notification information.

  The detection means 5 detects the intake of the sample container 11 when a sample container (not shown) for placing a sample is installed at a predetermined position of the analysis unit 1, and takes out the sample container 11 when removed from the predetermined position. To detect.

  The reading unit 6 is a barcode reader that reads a barcode attached to the sample container 11. A similar reading means 6 is provided for reading a barcode attached to the reagent container 21.

  The control unit 7 controls driving of each unit included in the analysis unit 1. Further, the control unit 7 receives the signal detected by the detection unit 5 and the information read by the reading unit 6, and causes the storage unit 8 to store the container loading / unloading information.

  The details of the analysis unit 1, details of the notification information displayed on the display means 42, details of the detection means 5, and details of container loading / unloading information will be described later.

[Analysis Department]
Next, details of the analysis unit 1 will be described.

  The analysis unit 1 includes a sample store 10, a reagent store 20, and a reaction store 30. In addition, around the outer periphery of the reaction chamber 30, a stirring unit 40 that promotes a reaction by stirring a liquid mixture of a sample and a reagent in a reaction vessel 31, a photometric unit 50 that measures light caused by the reaction, and a used unit A cleaning unit 60 for cleaning the reaction vessel 31 is provided upright. This sample storage 10 is an example of a “container”.

  A sample probe 71 for dispensing a sample from the sample container 11 in the sample container 10 to the reaction container 31 in the reaction container 30 is provided. The sample storage 10 rotates a predetermined angle to move a predetermined sample container 11 to a dispensing position (a position where the sample probe 71 can be dispensed). The operation of moving the sample container 11 to the dispensing position may be referred to as a dispensing operation.

  A reagent probe 72 for dispensing a sample from the reagent container 21 in the reagent storage 20 to the reaction container 31 is provided.

  Next, details of the sample storage 10 will be described with reference to FIGS. FIG. 2 is a cross-sectional view of the sample storage 10 taken along the rotation axis, and FIG. 3 is a plan view showing the detection means 5, the bottom plate 13, and the motor 15 excluding the lid member 12 and the like.

  As shown in FIG. 2, the sample store 10 includes a motor 15, a shaft 15 a, a holder 15 b, a handle 15 c, a sampler disk 16, a holding member 17, and a shaft-shaped member 18, in addition to the detection means 5, the lid member 12 and the bottom plate 13. And an urging means 19.

  The motor 15 is fixed to the center of the substantially circular bottom plate 13. The shaft 15a of the motor 15 extends upward, and a holder 15b is fixed to the upper end portion thereof. A sampler disk 16 is fixed to the holder 15b. Therefore, the sampler disk 16 is configured to rotate in conjunction with the motor 15.

(Holding member)
The sampler disk 16 is provided with a number of holding members 17 in the radial direction around the rotation axis. The holding member 17 is formed so as to hold the sample container 11 and allow the sample container 11 to be taken in and out.

  The holding member 17 holds the holding claw 171 that holds the outer peripheral wall of the sample container 11 and the bottom of the sample container 11, and generates frictional resistance with the bottom of the sample container 11, thereby And a rubber holding tray 172 that prevents general rotation. A through hole 173 communicating with the inside and the outside of the holding member 17 is provided at the center of the holding plate 172.

(Shaft-shaped member)
4 is a partially enlarged sectional view of FIG. As shown in FIGS. 2 and 4, the shaft-shaped member 18 is provided so as to fit in the through hole 173 and move between the inward position and the outward position of the holding member 17. Both end portions 181 of the shaft-shaped member 18 have a diameter larger than the diameter of the intermediate portion 182 so as not to be removed from the through hole 173. The shaft-shaped member 18 is an example of “an interlocking member”.

(Biasing means)
The urging means 19 urges the shaft-shaped member 18 inward (upward) of the holding member 17. An example of the urging means 19 is a compression coil spring that is wound around the intermediate portion 182 of the shaft-shaped member 18 and is compressed between the upper end 181 of the shaft-shaped member 18 and the holding plate 172. Yes.

  The biasing means 19 has a biasing force such that the biasing means 19 is further compressed by the weight of the sample container 11 put in the holding member 17 and is restored by taking the sample container 11 out of the holding member 17. By further compressing the urging means 19, most of the shaft-shaped member 18 moves to the outer position of the holding member 17 (the lower position of the holding tray 172) and is pushed downward. Further, by restoring the urging means 19, most of the shaft-like member 18 moves to the inward position of the holding member 17 (above the holding tray 172).

(Detection means)
As shown in FIG. 3, the detection means 5 is supported on the bottom plate 13 via a fixing member 131. The detecting means 5 detects the displacement of the sample container 11 when it is taken into the holding member 17 by detecting the movement of the shaft-shaped member 18 to the outward position. The detection means 5 detects the displacement of the sample container 11 when it is removed from the holding member 17 by detecting the movement of the shaft-shaped member 18 to the inward position.

  An example of the detection means 5 is an optical sensor in which a detection current flows in an electric circuit (not shown) when light is detected, and a detection current flows in the electric circuit when light is not detected. By disposing such detection means 5 below the holding member 17, when no detection current flows in the electric circuit, the shaft-like member 18 moves to an outward position (a position below the holding member 17) and emits light. When the blocking (start of container installation) is detected and the detection current flows through the electric circuit, the shaft-shaped member 18 moves to the inner position (above the holding member 17) and does not block the light (the container Detect installation end).

  The control unit 7 receives the detection current from the detection means 5 and determines the installation position of the container in accordance with the rotation angle of the sampler disk 16.

  Next, a method for managing the sample container 11 that is taken in and out of the holding member 17 will be described with reference to FIGS.

  When the detection means 5 detects the movement of the shaft-shaped member 18 downward (outward position of the holding member 17) and detects that the sample container 11 is put in the holding member 17, a reading command from the control unit 7 is detected. In response, the reading means (for example, a barcode reader) 6 reads identification information (for example, a barcode) attached to the sample container 11. The control unit 7 stores the read identification information of the sample container 11 and the identification information of the holding member 17 in the storage unit 8 in association with each other.

  FIG. 5 is a diagram showing the installation history of the sample container. As shown in FIG. 5, when the sample container 11 is installed by being placed in the holding member 17, the sample container 11 is placed in the holding member 17 in correspondence with the installation position identification information related to the holding member 17 and is read by the reading means 6. The identification information (sample container identification information) of the sample container 11 is written. Furthermore, the installation start time when the sample container 11 is put in the holding member 17 is written.

  FIG. 6 is a diagram showing the installation history of the sample container. As shown in FIG. 6, when the sample container 11 is taken out from the holding member 17, the installation end time when the sample container 11 is taken out from the holding member 17 in correspondence with the installation position identification information related to the holding member 17. Is written.

  Further, when a new sample container 11 is put into the holding member 17, a new sample container is put into the holding member 17 and read by the reading means 6 in accordance with the installation position identification information related to the holding member 17. 11 identification information (sample container identification information) is written.

  The control unit 7 determines that the sample container 11 has been replaced when different sample container identification information “1010” and “1012” are written in the same installation position identification information “001” (FIG. 6). (See the arrow marked with).

  The control unit 7 receives the result of detecting the removal of the sample container 11 and outputs an instruction to display the detected result on the display means 42 to the display control means 41. Details of notification of the detection result will be described later.

[Operation]
Next, a series of operations of the automatic analyzer will be briefly described with reference to FIG. FIG. 7 is a flowchart showing a series of operations of the automatic analyzer.

  The sample container 11 is put in the sample store 10, and the reagent container 21 is put in the reagent store 20 (step S101). The control unit 7 causes the storage unit 8 to store the installation start time, which is the time when the reagent container 21 is placed in the reagent storage 20 (described later). Each identification information attached to the sample container 11 and the reagent container 21 is read by the reading means 6 (step S102).

  Next, when a sample component measurement instruction is received (step S103). The control unit 7 causes the storage unit 8 to store the time when the sample component measurement instruction is received (measurement instruction time). When the measurement instruction for the sample component is received, the measurement of the sample component enters the end of the queue and waits for the queue. When the preceding measurement ends, sample dispensing is started (step S104). The control unit 7 causes the storage unit 8 to store the sample dispensing start time (dispensing start time).

  In the measurement of the sample components, the sample is dispensed from the sample container 11 and the reagent is dispensed from the reagent container 21 according to the measurement item. Thereby, a liquid mixture is produced and dispensing is completed. If there are a plurality of measurement items, a plurality of mixed liquids are generated (step S105). The controller 7 stores the dispensing end time (dispensing end time) in the storage unit 8.

  By analyzing the mixed solution, the measurement of the components of the sample is completed (step S106). The control unit 7 causes the storage unit 8 to store the measurement component end time (measurement end time).

  The installation start time, installation end time (described later), measurement instruction time, dispensing start time, dispensing end time, and measurement end time may be referred to as a reference time. Based on the reference time, the control unit 7 receives the result of detecting the removal of the sample container 11 and determines the time for notifying the detected result.

  FIG. 8 is a flowchart showing container removal detection. The container removal detection is performed in parallel with a series of operations (steps S101 to S106) of the automatic analyzer. As shown in FIG. 8, container detection (step S201), container removal notification (step S202), and continuation determination such as dispensing (step S203) are performed. The container detection (step S201) and the container removal notification (step S202) are performed for each container.

  Next, the operation for detecting the removal of the container will be described with reference to FIG. FIG. 9 is a flowchart showing container detection. As shown in FIG. 9, the control unit 7 determines whether or not a detection current is output from the detection unit 5 (step S301). This determination is made for each detection means 5.

  When it is determined that the detection current is output from the detection unit 5 (step S301: Yes), the control unit 7 determines whether the installation start time is stored in the storage unit 8 (step S302). When the installation start time is not stored (step S302: No), the process returns to the detection current output determination (step S301).

  When the installation start time is stored (step S302: Yes), the installation end time, which is the time when the sample container 11 is removed from the holding member 17, is associated with the installation position identification information of the storage unit 8 in the storage unit 8. Store (step S303).

  When the control unit 7 determines that the detection current is not output from the detection means 5 (step S301: No), the control unit 7 determines whether the installation start time is stored corresponding to the same installation position identification information (previous time). Is installed) (step S304). When there is no previous installation (step S304: No), the installation start time is stored in the storage unit 8 in association with the installation position identification information (step S305). At this time, the identification information of the sample container 11 is read as described in step S102. Next, the process returns to the detection current output determination (step S301).

  When there is a previous installation (step S304: Yes), the previous installation is left as history information, and a new installation start time is stored in the storage unit 8 (step S306). Next, the process proceeds to (Step S202).

  As described above, the control unit 7 determines the removal of the sample container 11 based on the previous installation in the storage unit 8 (the installation start time is already stored). Further, the control unit 7 notifies the removal of the container according to a predetermined notification time. The notification time is stored in a table (not shown) corresponding to the new installation start time and reference time (described above).

  Next, an example of an operation when notifying removal of the sample container 11 will be described with reference to FIG. FIG. 10 is a flowchart showing a notification mode according to the time when the removal of the container is detected. As shown in FIG. 10, the controller 7 reads “container” when the sample container 11 is taken out before the start of dispensing (step S401: Yes) and before the sample measurement instruction (step S402: Yes). Is taken out (before measurement instruction) ”is displayed to the display control means 41 (step S403). Next, the process proceeds to continuation determination (step S203).

  When the removal of the sample container 11 is before the start of dispensing (step S401: Yes) and after the sample measurement instruction is received (step S402: No), the control unit 7 “takes out the container (before dispensing). Is displayed to the display control means 41 (step S404). Next, the process proceeds to continuation determination (step S203).

  When the removal of the sample container 11 is after the start of dispensing (step S401: No) and before the end of the measurement (step S405: Yes), the control unit 7 “takes out the container (before the measurement is finished)”. Is displayed to the display control means 41 (step S406). Next, the process proceeds to continuation determination (step S203).

  In addition, when the removal of the container is after the start of dispensing (step S401: No) and after the end of the measurement (step S405: No), the control unit 7 determines that the measurement result is obtained even if the container is removed. In order not to cause any trouble, no notification will be given. Next, the process proceeds to continuation determination (step S203).

  Next, the determination operation for continuing the measurement will be described with reference to FIG. FIG. 11 is a flowchart showing a determination as to whether or not to continue dispensing based on the notification mode.

  As shown in FIG. 11, when there is a notification before the sample measurement instruction (step S501: Yes), when the operator selects continuation (step S502: Yes), a series of operations of the automatic analyzer continues, and the sample The measurement instruction is awaited (step S503). On the other hand, when the operator does not select continuation (step S502: No), a series of operations of the automatic analyzer is stopped (step S504).

  When there is a notification before dispensing (step S505: Yes), when the operator selects continuation (step S506: Yes), a series of operations of the automatic analyzer continues, and a waiting state for dispensing (step S506). S507). On the other hand, when the operator does not select continuation (step S506: No), a series of operations of the automatic analyzer is stopped (step S504).

  When there is a notification before the end of measurement (step S508: Yes), when the operator selects continuation (step S509: Yes), a series of operations of the automatic analyzer continues, and a state of waiting for dispensing is set (step). S510). On the other hand, when the operator does not select continuation (step S509: No), the series of operations of the automatic analyzer is stopped (step S504).

  On the other hand, when there is no notification before the end of measurement (step S508: No), the continuation determination ends. This is because even if the container is removed, the measurement result is not hindered because it is after the measurement is completed.

[Second Embodiment]
Next, a second embodiment will be described with reference to FIG. FIG. 12 is a partially enlarged sectional view of the sample storage. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  In the first embodiment, the biasing means 19 is formed independently of the holding member 17 and the shaft-like member 18. However, the function of biasing the shaft-like member 18 inward of the holding member 17 is shown. The urging means 19 having the above may be formed integrally with the holding member 17 and / or the shaft-like member 18.

  As shown in FIG. 12, the urging means 19 includes a thin-shaped bending portion 191 having a restoring force. The bending portion 191 is formed so as to connect the holding tray 172 and the shaft-shaped member 18. The bending portion 191 is deformed when the bottom portion 11a of the sample container 11 comes into contact with the holding plate 172, and moves the shaft-shaped member 18 to an outer position of the holding member 17 (a position below the holding plate 172). 11 is moved away from the holding plate 172 and moved to the inward position of the holding member 17 (above the holding plate 172).

  By forming the biasing means 19 integrally with the holding member 17 and the holding tray 172, the number of parts can be reduced, and the manufacturing cost and the assembly cost can be reduced. In addition, even if the bending part 191 is formed integrally with the holding member 17 or the holding plate 172, there is an effect of reducing the number of parts.

  In the embodiment, the configuration in which the removal of the sample container 11 is detected and the detection result is notified is shown. However, with the same configuration, the removal of the reagent container 21 is detected and the detection result is notified. May be.

  In the reagent storage 20, since the inside is in a constant temperature state, dew condensation may occur. In order not to be affected by this dew condensation, it is desirable to use a water-proof one for the detection means 5.

  Moreover, in the said embodiment, although the detection means 5 which detects the motion of the sample container 11 was shown, it is not limited to this, The detection means 5 is based on the image of the installation place of the sample container 11, and the presence or absence of a sample container May be detected. In other words, the detection means 5 includes an imaging means for acquiring an image of the installation location, a first image of the installation location when the sample container 11 acquired by the imaging means is placed, and the sample container 11 is placed. Whether or not the sample container 11 has been taken out may be detected based on the difference from the second image of the installation location when not installed.

  Furthermore, in order to clarify the difference between the first image and the second image, the mouth of the sample container 11 may be colored differently from the set location.

  Furthermore, a reflection member may be provided on the bottom 11a of the sample container 11, and the detection means 5 for irradiating the bottom 11a with light and detecting the reflected light from the bottom 11a may be provided.

  Furthermore, in the above-described embodiment, the shaft-shaped member 18 is provided so as to move above and below the holding tray 172. However, the present invention is not limited to this, and the shaft-shaped member 18 is moved outside and inside the side wall of the holding member 17. When the sample container 11 is taken into the holding member 17, the shaft-shaped member 18 moves to the outside of the side wall of the holding member 17, and when the sample container 11 is taken out from the holding member 17, it is The member 18 may move inside the side wall of the holding member 17.

  Although the shaft-like member 18 as described above is provided as an example of the interlocking member, a piece-like member 18a may be used.

  FIG. 13 is a diagram illustrating a modification of the interlocking member. As shown in FIG. 13, the piece-like member 18 a is provided so as to move from the inner wall of the holding member 17 to the advance position where it advances into the holding member 17 and to the retreat position where it retreats from the inside toward the inner wall side along the inner wall. When the sample container 11 is taken into the holding member 17, the piece-like member 18a is moved to the retracted position, and when the sample container 11 is taken out from the holding member 17, the piece-like member is moved to the advanced position by the urging force. May be.

  The piece-like member 18a is biased so as to move from the retracted position to the advanced position. The detecting means 5 irradiates the piece-like member 18a moved to the advance position with light, detects the reflected light from the piece-like member 18a, and detects the movement of the reflected light from the piece-like member 18a moved to the retracted position. .

  In the above-described embodiment, an example of the sample storage 10 that detects whether or not the sample container 11 containing the sample is taken out from the sample storage 10 before the sample is dispensed, and notifies the detection result. As described above, the present invention is not limited to this, and it is also applicable to the reagent storage 20 that detects whether the reagent container 21 containing the reagent has been taken out from the reagent storage 20 before the reagent is dispensed, and notifies the detection result. Is possible.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, rewrites, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Analysis part 2 Data processing part 3 Drive means 4 User interface 5 Detection means 6 Reading means 7 Control part 8 Storage means 10 Sample storage 11 Sample container 11a Bottom part 12 Lid member 13 Bottom plate 131 Fixing member 15 Motor 15a Shaft 15b Holder 15c Handle 16 Sampler disc 17 Holding member 171 Holding claw 172 Holding plate 173 Through hole
18 Shaft-shaped member 19 Biasing means 191 Deflection part 20 Reagent container 21 Reagent container 30 Reaction container 31 Reaction container 40 Agitation means 41 Display control means 42 Display means 43 Input means 43
50 Photometric unit 60 Cleaning unit 71 Sample probe 72 Reagent probe

Claims (6)

In an automatic analyzer that receives a measurement instruction, generates a liquid mixture by dispensing a sample and a reagent corresponding to the sample from the sample container and the reagent container, and measures the components of the sample by analyzing the liquid mixture.
A first container formed so that the sample container can be taken in and out;
A second container formed so that the reagent container can be taken in and out;
Detecting means for detecting whether the sample container or the reagent container has been taken out of the first container or the second container before the sample or the reagent is dispensed;
An informing means for informing the detected result;
An automatic analyzer characterized by comprising. An input means for inputting identification information attached to the sample container or the reagent container corresponding to the sample or the reagent;
The detection means includes a period from the input of the identification information to reception of the measurement instruction, a period from reception of the measurement instruction to start of the dispensing, and the dispensing from the start of dispensing. Detecting whether or not the sample container or the reagent container is taken out from the first container or the second container in at least one of the periods until the end of the injection, The automatic analyzer according to claim 1.   The notifying means is at least one of a period until the dispensing of the sample or the reagent is started, a period until the dispensing is completed, and a period until the result of analyzing the components of the mixed solution is output. The automatic analyzer according to claim 1 or 2, wherein notification is made during one period.   The detection means detects a displacement of the sample container or the reagent container when taken out from the first container or the second container. The automatic analyzer according to one item. Further comprising an interlocking member that interlocks with the taking in and out of the sample container or the reagent container,
The interlocking member has a shaft-like member that moves between an inner position of the first container or the second container and an outer position of the container;
When the sample container or the reagent container is taken out from the first container or the second container, the shaft-like member is moved from the outer position of the first container or the second container. When the sample container or the reagent container is moved to the inward position by the urging force and the sample container or the reagent container is taken into the first container or the second container, the shaft-like member is moved to the first container or the second container. Further comprising an urging means for moving against the urging force from the inward position of the container to the outward position,
The detection means detects the displacement of the sample container or the reagent container by detecting the shaft-like member moving to the inward position and the outward position and detecting the operation of the interlocking member. 5. The automatic analyzer according to claim 4, wherein The first container or the second container has a holding unit for holding the sample container or the reagent container,
The urging means is formed so as to connect the holding portion and the shaft-shaped member, and is deformed when the bottom portion of the sample container or the reagent container abuts to move the shaft-shaped member to the outward position. 6. The automatic analyzer according to claim 5, further comprising a deflecting member that is moved and restored by moving a bottom of the sample container or the reagent container to move the shaft member to the inward position.

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