Patent Document

RELATED APPLICATIONS 
     This application claims priority under 35 U.S.C. §119 to Japanese Patent Application No. JP2009-037415 filed on Feb. 20, 2009, the entire content of which is hereby incorporated by reference. 
     FIELD OF THE INVENTION 
     The present invention relates to an analyzing apparatus and analyzing method for performing re-examination of a sample, provided with a plurality of measuring units, and a transport device for transporting a sample for measurement to the plurality of measuring units. 
     BACKGROUND OF THE INVENTION 
     There are known conventional analyzers capable of assaying and reassaying a sample by transporting a sample (such as whole blood, serum, plasma, urine and the like) to the measuring units, such as biochemical analyzers, immunoanalyzers, blood cell analyzers, urine analyzers and the like. In such analyzers, the analysis result of a first assay of a sample (hereinafter referred to as a first examination) is compared to a normal value to determine whether the analysis result is abnormal, and remeasurement of the sample is performed when the analysis result is determined to be abnormal. 
     A re-examination of a sample is necessary when the analysis result of a predetermined measurement item is outside the normal range, or when an analysis result can not be accurately obtained due to an apparatus malfunction, sample deterioration or the like. However, when the sample analysis result is outside the normal range, it is not possible to determine from the analysis result whether the cause is an apparatus malfunction or some other reason. It is therefore desirable to re-measure the sample using a different measuring unit than the measuring unit that performed the first examination. 
     On the other hand, there are some cases which must have priority for rapidly obtaining the results of a remeasurement. To obtain the result by re-examination at an early stage, it is desirable to transport the sample to the measuring unit nearest the sample at the moment the first examination analysis result has been obtained. Since the sample analysis result can be obtained within a few minutes after the sample has been aspirated, there is an excellent possibility that the measuring unit that performed the first examination is the measuring unit nearest the sample. Therefore, whether the re-examination of the sample should be performed by the measuring unit that performed the first examination or performed by another measuring unit must be flexibly determined according to the situation. 
     US Patent Publication No. 2008/0310999 discloses an automatic analysis system provided with a plurality of analysis modules, and a transport device for transporting a sample to the plurality of analysis modules. In the automatic analysis system disclosed in US Patent Publication No. 2008/0310999, the analysis module that performs the reanalysis of a sample can be specified from among three types: “completely different module,” “different module priority,” and “processing power priority.” 
     When “completely different module” is specified, remeasurement is performed by a different analysis module than the analysis module that performed the first examination. When “different module” is specified, a different analysis module is a priority, however, the analysis module that performed the initial measurement may also perform the remeasurement when other analysis modules are under high load due to ongoing analyses. When “processing power priority” is specified, remeasurement is performed by the analysis module that has the greatest processing power. 
     SUMMARY OF THE INVENTION 
     The scope of the present invention is defined solely by the appended claims, and is not affected to any degree by the statements within this summary. 
     A first aspect of the present invention is an analyzing apparatus comprising: a transporting device for transporting a sample; a plurality of measuring units, each measuring unit measuring a sample transported by the transporting device; a determination result obtainer for obtaining a determination result representing whether the sample requires remeasurement based on a measurement result by a predetermined measuring unit among the plurality of measuring units; a designation receiver for receiving a designation of one measuring unit for remeasuring the sample determined to be remeasured; and a transport controller for controlling the transporting device so as to transport the sample determined to be remeasured to the designated measuring unit. 
     A second aspect of the present invention is an analyzing apparatus comprising: a transporting device for transporting a sample; a plurality of measuring units, each measuring unit measuring a sample transported by the transporting device; a determination result obtainer for obtaining a determination result representing whether the sample requires remeasurement based on a measurement result by a predetermined measuring unit among the plurality of measuring units; a time obtainer for obtaining, for each of the plurality of the measuring units, the time required to re-measure the sample determined to be remeasured; a selector for selecting, from among the plurality of measuring units, the measuring unit with the shortest time required to re-measure the sample as the measuring unit for remeasuring the sample; and a transport controller for controlling the transporting device so as to transport the sample determined to be remeasured to the selected measuring unit. 
     A third aspect of the present invention is an analyzing method executable by an analyzer comprising a transporting device for transporting a sample, and a plurality of measuring units, each measuring unit measuring a sample transported by the transporting device, the analyzing method comprising steps of: obtaining a determination result representing whether the sample requires remeasurement based on a measurement result by a predetermined measuring unit among the plurality of measuring units; receiving the designation of one measuring unit for remeasuring the sample determined to be remeasured; and controlling the transporting device so as to transport the sample determined to be remeasured to the designated measuring unit. 
     A fourth aspect of the present invention is an analyzing method executable by an analyzer comprising a transporting device for transporting a sample, and a plurality of measuring units, each measuring unit measuring a sample transported by the transporting device, the analyzing method comprising steps of: obtaining a determination result representing whether the sample requires remeasurement based on a measurement result by a predetermined measuring unit among the plurality of measuring units; obtaining, for each of the plurality of the measuring units, the time required to re-measure the sample determined to be remeasured; selecting, from among the plurality of measuring units, the measuring unit with the shortest time required to re-measure the sample as the measuring unit for remeasuring the sample; and controlling the transporting device so as to transport the sample determined to be remeasured to the selected measuring unit. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic view briefly showing the structure of a first embodiment of the analyzer of the present invention; 
         FIG. 2  is a perspective view of the exterior of a sample container; 
         FIG. 3  is a perspective view of the exterior of a sample rack; 
         FIG. 4  is a schematic view briefly showing the structure of the sample transporting device of the first embodiment of the analyzer of the present invention; 
         FIG. 5  is a block diagram showing the structure of the transport control device of the first embodiment of the present invention; 
         FIG. 6  is a block diagram showing the structure of the controller and the measuring unit of the first embodiment of the analyzer of the present invention; 
         FIG. 7  shows an example of a measuring unit configuration screen for configuring the measuring unit for performing the re-examination of a sample of the first embodiment of the analyzer of the present invention; 
         FIG. 8  shows an example of a configuration screen for configuring each measurement item of the measuring unit for performing the re-examination of a sample of the first embodiment of the analyzer of the present invention; 
         FIG. 9  is a flow chart showing the sequence of the re-examination process performed by the CPU of the transporting device of the first embodiment of the analyzer of the present invention; 
         FIG. 10  is a flow chart showing the sequence of the re-examination process performed by the CPU of the transporting device of a second embodiment of the analyzer of the present invention; 
         FIG. 11  is a schematic view briefly showing the structure of a third embodiment of the analyzer of the present invention; 
         FIG. 12  is a block diagram showing the structure of the controller of the third embodiment of the analyzer of the present invention; and 
         FIG. 13  is a flow chart showing the sequence of the re-examination process performed by the CPU of the transporting device of the third embodiment of the analyzer of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     First Embodiment 
       FIG. 1  is a schematic view briefly showing the structure of a first embodiment of the analyzer of the present invention. The first embodiment of the analyzer of the present invention is provided with a sample receiver  2  for receiving a sample rack containing sample containers, measuring units  5   a ,  5   b ,  5   c ,  5   d  for measuring a sample, sample transporting devices  3  for transporting the sample rack, sample holder  4  for holding the sample rack after sample collection, and transport control device  8 . The sample transporting devices  3  are respectively provided for the measuring units  5   a ,  5   b ,  5   c , and  5   d.    
     The measuring units  5   a ,  5   b ,  5   c ,  5   d  may be the same type of measuring unit, or may be different types of measuring units. The measuring units  5   a ,  5   b ,  5   c ,  5   d  are connected to a controller  9  via a LAN  7 . In the first embodiment, the controller  9  controls the operations of the measuring units  5   a ,  5   b ,  5   c , and  5   d.    
     The sample receiver  2  is configured to ship a sample rack holding a plurality of sample containers to the sample transporting device  3  on the farthest right in  FIG. 1 . The sample receiver  2  is controlled by the transport control device  8 , which is connected to the sample receiver  2  through the LAN  7  so as to be capable of data communication. 
     The transport control device  8  controls the sample receiver  2 , sample transporting device  3 , and sample holder  4  by obtaining information relating to the measuring units  5   a ,  5   b ,  5   c , and  5   d  stored in the controller  9 , for example, by obtaining identification information and information relating to the type of measuring unit. 
       FIG. 2  is a perspective view of the exterior of a sample container. As shown in  FIG. 2 , the sample container T is tube shaped with an open top end. A sample, for example blood collected from a patient, is accommodated in the interior of the sample container T, and the opening at the top end can be sealed by a cap C. A barcode label BL 1  bearing a printed barcode that identifies the sample is adhered to the side surface of the sample container T. 
       FIG. 3  is a perspective view of the exterior of a sample rack. As shown in  FIG. 3 , the sample rack L is configured so as to hold ten sample containers T in a vertical (upright) state. A barcode label BL 2  bearing a printed barcode identifying the sample rack L is adhered to the side surface of the sample rack L. 
     In the analyzer  1  shown in  FIG. 1 , four sample transporting devices  3  are disposed on the front side (the side at the bottom of  FIG. 1 ) of the measuring units  5   a ,  5   b ,  5   c , and  5   d . The sample rack L is delivered between adjacent sample transporting devices  3 . The sample transporting device  3  farthest to the right side in  FIG. 1  starts transporting the sample rack L received from the sample receiver  2 . The sample transporting device  3  farthest to the left side in  FIG. 1  transports the sample rack L to the sample holder  4 . 
       FIG. 4  is a schematic view briefly showing the structure of the sample transporting device  3  of the first embodiment of the present invention. As shown in  FIG. 4 , the sample transporting device  3  is provided with a first transport mechanism  31  for supplying a sample to a measuring unit, a second transport mechanism  32  for transporting a sample to a sample transporting device  3  (or sample holder  4 ) on the downstream side, and a controller  300  for controlling the second transport mechanism  32 . The first transport mechanism  31  is provided with a pre-analysis rack holder  33  capable of temporarily holding a plurality of sample racks L accommodating sample containers T that contain samples to be analyzed, a rack transporter  35  for linearly moving horizontally the sample rack L in the X direction in the drawing, a barcode reader  36  for reading the barcode label adhered to the sample rack L, a rack sensor  37  for detecting the presence of the sample rack L, sample container sensor  38  for detecting the presence of the sample container T, and a rack mover  39  for delivering the sample rack L to a post-analysis rack holder  34 . 
     The reanalysis rack holder  33  is quadrilateral in shape in planar view, with a width slightly larger than the width of the sample rack L. The reanalysis rack holder  33  becomes lower in stages from the circumferential surface so that the unanalyzed sample rack L is mounted on the top surface. The sample rack L is delivered from the second transport mechanism  32  to the reanalysis rack holder  33  by the rack feeder  322  of the second transport mechanism  32 , which is described later. 
     The rack sensor  37  is mounted near the reanalysis rack holder  33 , and the position at which the sample rack L is detected by the rack sensor  37  is the rack detection position  33   a . The sample rack L is transported from the second transport mechanism  32  to the rack detection position  33   a , where the rack sensor  37  detects the transported sample rack L. 
     A rack feeder  33   b , which is capable of extending toward the inner side, is provided on both side surfaces of the reanalysis rack holder  33 . When the sample rack L has been detected by the rack sensor  37 , the sample rack L is moved backward when the sample rack L engages the extended rack feeder  33   b  and is moved in this engaged state in a backward direction (a direction approaching the rack transporter  35 ). The rack feeder  33   b  is driven by a stepping motor  33   c  provided below the reanalysis rack holder  33 . 
     The rack transporter  35  transports, in the X direction, the sample rack L delivered by the reanalysis rack holder  33 . The sample container detection position  35   a  at which the sample container T is detected by the sample container sensor  38 , and the sample supplying position  35   c  at which the sample is supplied to the measuring unit are present on the transport path of the sample rack L moved by the rack transporter  35 . The rack transporter  35  moves the sample rack L through the sample container detection position  35   a  to the sample supplying position  35   c.    
     The sample supplying position  35   c  is a position downstream the distance of one sample in the transport direction from the sample container detection position  35   a , so that when a sample is transported to the sample supplying position  35   c  by the rack transporter  35 , the sample container T is grasped by the hand of the measuring unit and removed from the sample rack L, and the sample is supplied to the measuring unit by aspirating the sample from the sample container T. After the rack transporter  35  has transported the sample container T to the sample supplying position  35   c , the transport of the sample rack L is stopped while the supplying of the sample is completed and the sample container T is returned to the sample rack L. 
     The rack transport  35  has two belts, a first belt  351  and a second belt  352 , which operate independently. The widths in the arrow Y direction of the first belt  351  and second belt  352  are respectively less than half of the width B of the sample rack L in the arrow Y direction. The first belt  351  and second belt  352  are arranged in parallel so as to not protrude beyond the width B in the arrow Y direction of the sample rack L when the sample rack L is transported by the rack transporter  35 . The sample rack L can be transported in the X direction and the opposite direction by controlling the movement direction of the first belt  351  and second belt  352 . 
     The barcode reader  36  reads the barcode of the barcode label BL 1  adhered to the sample container T, and reads the barcode of the barcode label BL 2  adhered to the sample rack L as shown in  FIGS. 2 and 3 . The barcode reader  36  reads the sample barcode of the sample container T as the sample container T is rotated in a horizontal direction by a rotating device while held in the sample rack L. Even when the barcode label BL 1  of the sample container T is positioned on the opposite side from the barcode reader  36 , the barcode label BL 1  can be turned toward the barcode reader  36  by rotating the sample container T, thus allowing the barcode reader  36  to read the sample barcode. The rack barcode of the sample rack L records the rack ID allocated to each sample rack L, and this information is used in managing the sample analysis results. 
     The rack sensor  37  and the sample container sensor  38  are contact type sensors, respectively configured by a contact piece, light emitting element for emitting light, and light receiving element. The rack sensor  37  and the sample container sensor  38  are curved by the contact piece coming into contact with a detection object, and as a result the light emitted from the light emitting element is reflected by the contact piece and impinges the light receiving element. Thus, the sample container T can be detected as the contact piece is bent by the sample container T when the detection object, that is the sample container T containing the sample, passes below the sample container sensor  38 . 
     The rack mover  39  is disposed so as to face the post-analysis rack holder  34  with the rack transporter  35  interposed therebetween, and the rack mover  39  is moved horizontally in the Y direction via the drive force of a stepping motor  39   a . Thus, the sample rack L is pushed into the post-analysis rack holder  34  by moving the rack mover  39  to the post-analysis rack holder  34  side when the sample rack L is transported to a position  391  between the post-analysis rack holder  34  and the rack mover  39  (hereinafter referred to as post-analysis rack transport position). The analyzed sample rack L is therefore moved from the first transport mechanism  31  to the second transport mechanism  32 . 
     The second transport mechanism  32  is configured by the rack mover  321 , rack feeder  322 , and post-analysis rack holder  34 . The rack mover  321  extends in the arrow X direction in the drawing, and is capable of linearly moving horizontally the sample rack L in the arrow X direction. The rack mover  321  has an endless belt  321   a  and a stepping motor  321   b , and the belt  321   a  is moved in the arrow X direction by the drive force of the stepping motor  321   b . The sample rack L mounted above the belt  321   a  can therefore be transported in the X direction. 
     The rack feeder  322  is positioned on the front side of the reanalysis rack holder  33  so as to face the reanalysis rack holder  33  with the rack mover  321  interposed therebetween, and is linearly moved horizontally in the Y arrow direction by the drive force of the stepping motor  322   a . Thus, the sample rack L is pushed to the rack detection position  33   a  within the reanalysis rack holder  33  by moving the rack feeder  322  to the reanalysis rack holder  33  side when the sample rack L is transported to a position  323  between the reanalysis rack holder  33  and the rack feeder  322  (hereinafter referred to as reanalysis rack transport position). 
     The post-analysis rack holder  34  is quadrilateral in shape in the planar view, with a width slightly larger than the width of the sample rack L. The post-analysis rack holder  34  becomes lower in stages from the circumferential surface so that the analyzed sample rack L is mounted on the top surface. The sample rack L is delivered from the rack transporter  35  to the post-analysis rack holder  34  by the rack mover  39 . 
     A rack feeder  34   b , which is capable of extending toward the inner side, is provided on both side surfaces of the post-analysis rack holder  34 . When the sample rack L has been moved by the rack mover  39 , the sample rack L is then moved forward when the sample rack L is engaged by the extended rack feeder  34   b  and moved forward in the engaged state (in a direction approaching the rack mover  321 ). The rack feeder  34   b  is driven by a stepping motor  34   c  provided below the post-analysis rack holder  34 . 
     The sample rack L transporting operation performed by the sample transporting device  3  is controlled by the transport control device  8 , which is connected to the sample transport device  3  via the LAN  7  so as to be capable of data communication. That is, the transport control device  8  controls the operation of receiving the sample rack L performed by the sample receiver  2 , the operation of transporting the sample rack L performed by the sample transporting device  3 , and the operation of receiving the sample rack L performed by the sample holder  4 . 
     Note that the sample receiver  2 , sample transporting device  3 , and sample holder  4  are respectively provided with a controller  200 ,  300 ,  400 , which is configured by a CPU, ROM, RAM and the like, as shown in  FIG. 1 . The transport control device  8  is capable of controlling the operations of the sample receiver  2 , sample transporting device  3 , and sample holder  4  via data communication with the controllers  200 ,  300 ,  400  of the sample receiver  2 , sample transporting device  3 , and sample holder  4 . The control device  9  is also connected so as to be capable of data communication with the controllers  200 ,  300 ,  400  of the sample receiver  2 , sample transporting device  3 , and sample holder  4 . 
       FIG. 5  is a block diagram showing the structure of the transport control device  8  of the first embodiment of the present invention. As shown in  FIG. 5 , the transport control device  8  is configured by a CPU  81 , RAM  82 , memory  83 , I/O interface  84 , video interface  85 , portable disk drive  86 , communication interface  87 , and an internal bus  88 , which is connected to all these hardware components. 
     The CPU  81  is connected to each hardware component of the transport control device  8  via the internal bus  88 , so as to control the operation of each hardware component, and execute the functions of various software in accordance with a transport control program  101  stored in the memory  83 . The RAM  82  is a volatile memory such as SRAM, DRAM or the like, and is used to expand loaded modules during the execution of the transport control program  101 , and to store the temporary data generated during the execution of the transport control program  101 . 
     The memory  83  is configured by an internal fixed storage device (hard disk), ROM or the like. The transport control program  101  stored in the memory  83  may be downloaded by the portable disk drive  86  from a portable recording medium  80  such as a DVD or CD-ROM on which information such as programs and data are recorded, and expanded from the memory  83  to the RAM  82  during execution of the program. Of course, computer programs such as the transport control program  101  may also be downloaded from a peripheral computer connected to an external network through the communication interface  87 . 
     The memory  83  is also provided with a transport control information memory  831  for storing transport control information such as configuration item information and the like for transport control according to the type of measuring unit connected to the LAN  7 . 
     The communication interface  87  is connected to the internal bus  88  so as to be capable of sending and receiving data to/from an external computer by means of connection to an external network such as a LAN, WAN, or the Internet. In the first embodiment, the control device  9 , sample transporting devices  3  and the like are connected via the LAN  7 . 
     The I/O interface  84  is connected to an input unit  110  such as a keyboard and mouse or the like, so as to receive data input. The video interface  85  is also connected to an image display unit  120  such as a CRT monitor, LCD or the like, so as to display predetermined images. 
     The measuring units  5   a ,  5   b ,  5   c ,  5   d  may be all of the same type or may be of different types. In the first embodiment, the measuring units  5   a ,  5   b ,  5   c  are all of the same type, but the remaining measuring unit  5   d  is a different type of measuring unit. Specifically, the measuring units  5   a ,  5   b ,  5   c  are blood cell counters for counting blood cells using both an electrical resistance method and optical method. The measuring unit  5   d  is a smear sample preparing device for preparing a smear sample. 
     Note that the measuring units  5   a ,  5   b ,  5   c ,  5   d  are not limited to these types and may be urine analyzers, blood coagulation measuring devices, immunoanalyzers, gene amplification measuring apparatuses or the like. 
       FIG. 6  is a block diagram showing the structure of the control device  9  and measuring units  5   a ,  5   b ,  5   c ,  5   d  of the first embodiment of the present invention. In the example of  FIG. 6 , a structural example is shown of the blood cell counting apparatus, that is, measuring unit  5   a  ( 5   b ,  5   c ). As shown in  FIG. 6 , the measuring unit  5   a  ( 5   b ,  5   c ) is configured by a sample obtainer  50 , drive circuit  501  for driving the sample obtainer  50 , sample preparing section  52 , drive circuit  502  for driving the sample preparing section  52 , detection section  53 , drive circuit  503  for driving the detection section  53 , and waveform processing circuit  504  for performing waveform processing of the electrical signals output from the detection section  53 . 
     The sample obtainer  50  and sample preparing section  52  are respectively driven by the drive circuit  501  and the drive circuit  502  via control signals corresponding to control data stored in a register  505 . The detection section  53  converts, for example, the obtained optical signals to electrical signals. The waveform processing circuit  504  amplifies the electrical signals converted and transmitted by the detection section  53 , and performs waveform processing of the amplified electrical signals. The register  505  stores the electrical signals that have been subjected to waveform processing by the waveform processing circuit  504 . 
     The communication interface  506  is a LAN interface connected by a LAN cable  70  to a communication interface  97  of the control device  9 . Thus, a processor  507  transmits information relating to the measuring unit  5   a  ( 5   b ,  5   c ) to the control device  9  when a transmission request signal for information relating to the measuring unit  5   a  ( 5   b ,  5   c ) is received from the control device  9 . 
     The control device  9  is configured by a CPU  91 , RAM,  92 , memory  93 , I/O interface  94 , video interface  95 , portable disk drive  96 , communication interface  97 , and an internal bus  98  connecting these hardware components. 
     The CPU  91  is connected to each hardware component of the control device  9  via the internal bus  98 , so as to control the operation of each hardware component, and execute the functions of various software in accordance with an operation control program  102  stored in the memory  93 . The RAM  92  is a volatile memory such as SRAM, DRAM or the like, and is used to expand loaded modules during the execution of the operation control program  102 , and to store the temporary data generated during the execution of the operation control program  102 . 
     The memory  93  is configured by an internal fixed storage device (hard disk), ROM or the like. The operation control program  102  stored in the memory  93  may be downloaded by the portable disk drive  96  from a portable recording medium  90  such as a DVD or CD-ROM on which information such as programs and data are recorded, and expanded from the memory  93  to the RAM  92  during execution of the program. Note that computer programs such as the operation control program  102  may also be downloaded from a peripheral computer connected to an external network through the communication interface  97 . 
     The memory  93  is provided with a measuring unit information memory  931  for storing measuring unit information including the identification information of the connected measuring units  5   a ,  5   b ,  5   c ,  5   d , and information relating to the measured results. 
     The communication interface  97  is connected to the internal bus  98  so as to be capable of sending and receiving data to/from an external computer by means of connection to an external network such as a LAN, WAN, or the Internet. In the first embodiment, the control device  9  is connected to the transport control device  8  and sample transporting devices  3  and the like via the LAN  70 . 
     The I/O interface  94  is connected to an input unit  130  such as a keyboard and mouse or the like, so as to receive data input. The video interface  95  is also connected to an image display unit  140  such as a CRT monitor, LCD or the like, so as to display predetermined images. 
     In the analyzer of the first embodiment of the present invention, the measuring unit  5   a  performs the first examination of the sample, and a determination is made as to whether a re-examination must be performed. When it has been determined that re-examination is required, the sample to be re-examined must be transported to the measuring unit which is to perform the re-examination. That is, when the re-examination is to be performed by the measuring unit that performed the first examination, the sample rack L holding the sample container T containing the sample to be re-examined must be transported back to the sample supplying position  35   c . When the re-examination is performed by the measuring unit  5   b  or  5   c , which is a different measuring unit from the measuring unit  5   a  that performed the first examination, the sample rack L holding the sample container T containing the sample to be re-examined must be transported to the measuring unit  5   b  or  5   c.    
     Configurations preset by the user through the image display  120  of the transport control device  8  are received beforehand whether the re-examination of the sample is performed by the measuring unit  5   a  or one of the measuring units  5   b  or  5   b .  FIG. 7  shows an example of a measuring unit configuration screen for configuring the measuring unit for performing the re-examination of a sample of the first embodiment of the analyzer  1  of the present invention. 
     In the measuring unit configuration screen shown in  FIG. 7 , a configuration for whether to perform a re-examination is first received by clicking a mouse or the like on a radio button or the like. This configuration may also be received through a selection button or the like on a pulldown menu. Note that an erroneous configuration can be avoided before the occurrence by validating the radio button of the re-examination unit configuration only when a “perform re-examination” configuration has been received. 
     When a “perform re-examination” configuration has been received, the configuration of the measuring unit to perform the re-examination (re-examination measuring unit) may then be received. When a “same unit” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit  5   a  that performed the first examination. Therefore, instructions are transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit  5   a.    
     When a “different unit” configuration has been received, the sample determined to require re-examination is re-examined by either the measuring unit  5   b  or  5   c . Note that performing the re-examination by either the measuring unit  5   b  or  5   c  can be selected based on predetermined selection conditions that have been set previously. For example, the measuring unit nearest the detected position of the sample rack L holding the sample container T containing the sample to be re-examined may be selected, or the measuring unit with the fewest number of sample racks L awaiting examination may be selected by precounting the number of sample racks L being transported to the respective measuring units  5   b  and  5   c . The measuring unit that has the lightest processing load may also be selected by precalculating the processing loads of the processors  507  of the respective measuring units  5   b  and  5   c . Instructions are then transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the selected measuring unit  5   b  or  5   c.    
     When an “assign” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit assigned by the user. Assigning a measuring unit may also be accomplished by, for example, a pulldown menu. In this case, instructions are transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the assigned measuring unit. 
     When an “unassigned” configuration has been received, the sample determined to require re-examination is re-examined by a measuring unit selected based on a predetermined condition. Note that the selection of any measuring unit may be accomplished by presetting predetermined selection conditions. For example, the measuring unit nearest the sample rack L holding the sample container T containing the sample to be re-examined at the moment the transport control device  8  has received the re-examination order signal from the control device  9  may be selected, or the measuring unit with the fewest number of sample racks L awaiting examination may be selected by precounting the number of sample racks L being transported to the respective measuring units  5   a ,  5   b , and  5   c.    
     The measuring unit that has the lightest processing load may also be selected by precalculating the processing loads of the processors  507  of the respective measuring units  5   a ,  5   b , and  5   c . Instructions are then transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the selected measuring unit. 
     The selection information of the measuring unit for performing the re-examination, which has been configured on the measuring unit configuration screen shown in  FIG. 7 , is stored in the transport control information memory  831  of the transport control device  8 . The CPU  81  of the transport control device  8  obtains the information relating to the transport priority of the sample to be re-examined by referencing the selection information of the measuring units stored in the transport control information memory  831 . 
     The configuration of the measuring unit for performing the re-examination may also be received for each measurement item. In this case, a plurality of measurement items are prestored as determination conditions in the memory  83  of the transport control device  8 , and the configuration of the selection conditions of the measuring unit are received when re-examination is to be performed for individual measurement items.  FIG. 8  shows an example of a configuration screen for configuring each measurement item of the measuring unit for performing the re-examination of the first embodiment of the analyzer  1  of the present invention. 
     In the measuring unit configuration screen shown in  FIG. 8 , the configuration of whether to perform re-examination is received for each measurement item  71  by clicking the mouse or the like on a button  72 . This configuration may also be received through a radio button or the like on a pulldown menu. The items displayed in the measurement items  71  are read from the measurement items stored as determination conditions in the memory  83 . In  FIG. 8 , the items received for the configuration are batched. Note that an erroneous configuration can be avoided before the occurrence by validating the radio button of the re-examination unit configuration only when a “perform re-examination” configuration has been received. 
     The “same unit” configuration is specified in the example of  FIG. 8  in relation to the “abnormal red blood cell count” and “abnormal white blood cell count” configuring the measuring unit for performing the re-examination when an abnormality has been detected in the red blood cell count and white blood cell count measurement items. In this case, the sample determined to require re-examination is re-examined by the measuring unit  5   a . Therefore, instructions are transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit  5   a.    
     The “other unit” configuration is specified in the example of  FIG. 8  in relation to the “white blood cell fraction” configuring the measuring unit for performing the re-examination when an abnormality has been detected in the white blood cell fraction measuring item. In this case, the sample determined to require re-examination is re-examined by the measuring unit  5   b  or  5   c . Note that the selection of either measuring unit  5   b  or  5   c  may also be accomplished by presetting a predetermined selection condition. For example, the measuring unit nearest the detected position of the sample rack L holding the sample container T containing the sample to be re-examined may be selected, or the measuring unit with the fewest number of sample racks L awaiting examination may be selected by precounting the number of sample racks L being transported to the respective measuring units  5   b  and  5   c . The measuring unit that has the lightest processing load may also be selected by precalculating the processing loads of the processors  507  of the respective measuring units  5   b  and  5   c . Instructions are then transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the selected measuring unit  5   b  or  5   c.    
     When the “assign  5   c ” configuration is received, the sample determined to require re-examination is re-examined by the assigned measuring unit  5   c . Although only the measuring unit  5   c  is assigned in the example of  FIG. 8 , such assignment is not specifically limited. In this case, instructions are then transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the assigned measuring unit  5   c.    
     When an “unassigned” configuration has been received, the sample determined to require re-examination is re-examined by a measuring unit assigned based on a predetermined condition. Note that the selection of any measuring unit may be accomplished by presetting predetermined selection conditions. For example, the measuring unit nearest the sample rack L holding the sample container T containing the sample to be re-examined at the moment the transport control device  8  has received the re-examination order signal from the control device  9  may be selected, or the measuring unit with the fewest number of sample racks L awaiting examination may be selected by precounting the number of sample racks L being transported to the respective measuring units  5   a ,  5   b , and  5   c . The measuring unit that has the lightest processing load may also be selected by precalculating the processing loads of the processors  507  of the respective measuring units  5   a ,  5   b , and  5   c . Instructions are then transmitted from the CPU  81  of the transport control device  8  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the selected measuring unit. 
     The selection information of the measuring unit for performing the re-examination, which has been configured on the measuring unit configuration screen shown in  FIG. 8 , is stored in the transport control information memory  831  of the transport control device  8 . The CPU  81  of the transport control device  8  obtains the information relating to the transport priority of the sample to be re-examined by referencing the selection information of the measuring units stored in the transport control information memory  831 . 
     Whether or not re-examination is required may also be determined based on whether or not the obtained measurement data are within a normal range by storing a normal range of normal measurement values in the memory  93  of the control device  9  to be used for determining whether the measurement value of each measurement item is normal. In this case, an item may be provided for receiving the configuration of a normal range for each measurement item in the example of  FIG. 8 . Note that overlooking a sample that requires re-examination can be prevented before the occurrence and needless re-examination can be avoided by suitably configuring a normal range for each measurement item. A configured normal range for each measurement item is stored in the memory  93  of the control device  9  through the LAN  7 . 
       FIG. 9  is a flow chart showing the sequence of the re-examination process performed by the CPU  81  of the transport control device  8  of the analyzer  1  of the first embodiment of the present invention. In  FIG. 9 , the CPU  81  of the transport control device  8  of the analyzer  1  of the first embodiment determines whether a re-examination order signal, which specifies the execution of re-examination, has been received from the CPU  91  of the control device  9 . That is, the CPU  81  determines that re-examination is required when a re-examination order signal, which specifies the execution of re-examination, has been received from the CPU  91 , and determines that re-examination is not required when a re-examination order signal, which specifies the execution of re-examination, has not been received from the CPU  91  within a predetermined time. Note that the CPU  91  of the control device  9  determines whether re-examination is required based on a predetermined condition, and transmits a re-examination order signal to the transport control device  8  when re-examination is required, and does not transmit a re-examination order signal when re-examination is not required. The CPU  81  then awaits reception when the CPU  81  has determined that a re-examination order signal has not been received (step S 901 : NO). 
     The re-examination order signal includes not only the information contained in the first order information, for example, the patient ID that identifies the patient and the sample ID contained in the barcode information as information identifying the sample, but also includes the measuring unit ID that identifies the measuring unit that performed the first examination, as well as the measurement items determined to require re-examination. When the CPU  81  has determined that a re-examination order signal has been received (step S 901 : YES), the CPU  81  references the measuring unit selection information stored in the transport control information memory  831  (step S 902 ), and specifies the measuring unit that has the transport priority for the sample determined to require re-examination (step S 903 ). 
     The CPU  81  determines whether the specified measuring unit is the same measuring unit that performed the first examination. When the CPU  81  determines that the specified measuring unit is the same measuring unit that performed the first examination (step S 904 : YES), the CPU  81  transmits instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit that performed the first examination (step S 905 ). 
     When the CPU  81  determines that the specified measuring unit is not the same measuring unit that performed the first examination (step S 904 : NO), the CPU  81  transmits instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined to the specified measuring unit (step S 906 ). 
     According to the first embodiment described above, an analyzer is provided that is capable of realizing both a demand to perform re-examination by a different measuring unit than that which performed the first examination and a demand to obtain analysis results quickly for a sample determined to require re-examination by respectively receiving a configuration of the measuring unit that performed the first examination capable of obtaining an analysis result most quickly, or a configuration of another measuring unit different than the measuring unit that performed the first examination. 
     Second Embodiment 
     Since the structure of the analyzer  1  of the second embodiment of the present invention is identical to the structure of the analyzer  1  of the first embodiment and like parts are designated by like reference numbers, detailed description is therefore abbreviated. The second embodiment differs from the first embodiment in that the CPU  81  controls the sample transporting devices  3  so as to transport the sample to the measuring device capable of obtaining the analysis result in the shortest time by calculating, the analysis result obtaining time for each measuring unit, that is, the time needed to obtain the analysis result of re-examination at the moment the sample has been determined to require re-examination. 
     Accordingly, whether re-examination is performed by the measuring unit  5   a  that performed the first examination, or re-examination is performed by the measuring unit  5   b  or  5   c  does not need to be preconfigured by the user through the image display  120  of the transport control device  8 , nor by the measuring unit configuration screen for configuring the measuring unit for performing the re-examination. That is, the processing is identical to when the “unassigned” configuration is specified in the first embodiment. 
     When a predetermined sample has been determined to require re-examination, the CPU  81  of the transport control device  8  detects the current position of the sample rack L holding the sample container T containing the sample to be re-examined, and calculates, for the measuring unit of each transport priority, the analysis result obtaining time from the aspiration of the transported sample until the analysis result is obtained. The analysis result obtaining time may also be the transport time from the current position of the sample rack L holding the sample container T containing the sample to be re-examined, or a time converted the number of sample awaiting measurement for each measuring unit. These times may also be combined, and index calculated for a comprehensive determination. 
       FIG. 10  is a flow chart showing the sequence of the re-examination process performed by the CPU  81  of the transport control device  8  of the analyzer  1  of the second embodiment of the present invention. In  FIG. 10 , the CPU  81  of the transport control device  8  of the analyzer  1  of the second embodiment determines whether a re-examination order signal, which specifies the execution of re-examination, has been received from the CPU  91  of the control device  9  (step S 1001 ). The CPU  81  then awaits reception when the CPU  81  has determined that a re-examination order signal has not been received (step S 1001 : NO). 
     The re-examination order signal includes not only the information contained in the first order information, for example, the patient ID that identifies the patient and the sample ID contained in the barcode information as information identifying the sample, but also includes the measuring unit ID that identifies the measuring unit that performed the first examination, as well as the measurement items determined to require re-examination. When the CPU  81  determines that a re-examination order signal has been received (step S 1001 : YES), the CPU  81  calculates the analysis result obtaining time for each measuring unit (step S 1002 ). The CPU  81  selects the measuring unit with the shortest calculated analysis result obtaining time as the measuring unit for performing re-examination (step S 1003 ). 
     The CPU  81  determines whether the selected measuring unit is the same measuring unit that performed the first examination (step S 1004 ). When the CPU  81  determines that the selected measuring unit is the same measuring unit that performed the first examination (step S 1004 : YES), the CPU  81  transmits instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit that performed the first examination (step S 1005 ). 
     When the CPU  81  has determined that the selected measuring unit is another measuring unit that is different than the measuring unit that performed the first examination (step S 1004 : NO), the CPU  81  transmits instruction to transport, to the selected measuring unit, the sample rack L holding the sample container T containing the sample to be re-examined (step S 1006 ). 
     According to the second embodiment, the analysis result obtaining time required to re-examine a sample determined to require re-examination is calculated for each measuring unit, and the measuring unit with the shortest calculated analysis result obtaining time is selected as the measuring unit for re-examining the sample. The re-examination analysis result can be obtained early by automatically selecting the measuring unit with the shortest analysis result obtaining time as the measuring unit for performing the re-examination by performing controls to transport the sample determined to require re-examination to the selected measuring unit. 
     Note that not only is the measuring unit with the shortest calculated analysis result obtaining time selected as the measuring unit to perform the re-examination, the calculated analysis result obtaining times may also be displayed on the screen display  120  so that the user may also select a measuring unit to perform the re-examination based on the displayed analysis result obtaining times. In this case, the measuring unit with the shortest analysis result obtaining time can be selected as the measuring unit to perform re-examination by having the transport control device  8  perform controls to transport the sample determined to require re-examination to the selected measuring unit. 
     Third Embodiment 
       FIG. 11  is a schematic view briefly showing the structure of the analyzer  1  of a third embodiment of the present invention. The analyzer  1  of the third embodiment of the present invention is provided with two measuring units including a first measuring unit  5   a  and second measuring unit  5   b  that are mutually of the same type, sample transporting device (transporting device)  3  disposed on the front side of the first measuring unit  5   a  and the second measuring unit  5   b , and a control device  12  configured by a PC (personal computer) electrically connected to the first measuring unit  5   a , second measuring unit  5   b , and sample transporting device  3 . 
     In the third embodiment, the first measuring unit  5   a  and the second measuring unit  5   b  are the same type of measuring unit, which measure a sample by measuring the same items using the same measurement principle. Note that in this case the same type of measuring unit not only includes the two measuring units  5   a  and  5   b  which measure a sample for completely identical measurement items, but also includes cases wherein a plurality of measurement items measured by the first measuring unit  5   a  and a plurality of measurement items measured by the measuring unit  5   b  are partially in common to both measuring units. 
     The first measuring unit  5   a  and the second measuring unit  5   b  are arranged in parallel. Furthermore, the first measuring unit  5   a  and the second measuring unit  5   b  measure predetermined measurement items of a sample aspirated, by an internal sample aspirating section and accessed through ports  51   a  and  51   b  provided in the housing, from sample container T held in a sample rack L transported by the sample transporting device  3 . 
     The control device  12  is configured by a personal computer (PC) or the like.  FIG. 12  is a block diagram showing the structure of the control device  12  of the analyzer  1  of the third embodiment of the present invention. As shown in  FIG. 12 , the control device  12  is configured by a CPU  121 , RAM  122 , memory  123 , I/O interface  124 , video interface  125 , portable disk drive  126 , communication interface  127 , and an internal bus  128 , which is connected to all these hardware components. 
     The CPU  121  is connected to each hardware component of the control device  12  via the internal bus  128 , so as to control the operation of each hardware component, and execute the functions of various software in accordance with a transport control program  101  stored in the memory  123 . The RAM  122  is a volatile memory such as SRAM, DRAM or the like, and is used to expand loaded modules during the execution of the transport control program  101 , and to store the temporary data generated during the execution of the transport control program  101 . 
     The memory  123  is configured by an internal fixed storage device (hard disk), ROM or the like. The transport control program  101  stored in the memory  123  may be downloaded by the portable disk drive  126  from a portable recording medium  80  such as a DVD or CD-ROM on which information such as programs and data are recorded, and expanded from the memory  123  to the RAM  122  during execution of the program. Note that computer programs such as the transport control program  101  may also be downloaded from a peripheral computer connected to an external network through the communication interface  127 . The memory  123  is provided with a transport control information memory  1231  for storing transport control information, such as the configuration item information for transport control, for each measuring unit  5   a  and  5   b.    
     The communication interface  127  is connected to the internal bus  128  so that the control device  12  is capable of sending and receiving data to/from an external computer by means of connection to an external network such as a LAN, WAN, or the Internet. 
     The I/O interface  124  is connected to an input unit  12   b  such as a keyboard and mouse or the like, so as to receive data input. The video interface  125  is connected to an image display  12   a  such as a CRT monitor, LCD or the like to display predetermined images. 
     The brief structure of the sample transporting device  3  is identical to that of the first embodiment and like parts are designated by like reference numbers; therefore detailed description is abbreviated. Note that the reanalysis rack holder  33  is quadrilateral in shape in planar view, with a width slightly larger than the width of the sample rack L. The reanalysis rack holder  33  becomes lower in stages from the circumferential surface so that the sample rack L, which holds the reanalysis sample containers T, is mounted on the top surface. 
     The post-analysis rack holder  34  is also quadrilateral in shape in the planar view, with a width slightly larger than the width of the sample rack L. The post-analysis rack holder  34  becomes lower in stages from the circumferential surface so that the post analysis sample rack L is mounted on the top surface. 
     In the analyzer of the third embodiment of the present invention, the measuring unit  5   a  performs the first examination of the sample, and a determination is made as to whether a re-examination must be performed. When it has been determined that re-examination is required, the sample to be re-examined must be transported to the measuring unit which is to perform the re-examination. That is, when the re-examination is to be performed by the measuring unit that performed the first examination, the sample rack L holding the sample container T containing the sample to be re-examined must be transported back to the sample supplying position  35   c . When the re-examination is performed by the measuring unit  5   b , the sample rack L holding the sample container T containing the same to be re-examined must be transported to the adjacent measuring unit  5   b.    
     Whether the measuring unit  5   a  performs the re-examination or the measuring unit  5   b  performs the re-examination can be preconfigured by the user through the image screen  12   a  of the control device  12 . The measuring unit configuration screen displayed on the image display  12   a  is identical to that of first embodiment shown in  FIG. 7 . 
     When a “perform re-examination” configuration has been received, the configuration of the measuring unit (re-examination unit) to perform the re-examination (re-examination measuring unit) is received. When a “same unit” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit  5   a  that performed the first examination. Therefore, instructions are transmitted from the CPU  121  of the control device  12  to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit  5   a.    
     When a “different unit” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit  5   b . The CPU  121  of the control device  12  issues instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the measuring unit  5   b.    
     When an “assign” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit assigned by the user. Assigning a measuring unit may also be accomplished by, for example, a pulldown menu. In this case, instructions are transmitted from the CPU  121  of the control device  12  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the assigned measuring unit. 
     When an “unassigned” configuration has been received, the sample determined to require re-examination is re-examined by the measuring unit selected based on a predetermined condition. Note that the selection of any measuring unit may be accomplished by presetting predetermined selection conditions. For example, the measuring unit nearest the detected position of the sample rack L holding the sample container T containing the sample to be re-examined may be selected, or the measuring unit with the fewest number of sample racks L awaiting examination may be selected by precounting the number of sample racks L being transported to the respective measuring units  5   a  and  5   b . The measuring unit that has the lightest processing load may also be selected by precalculating the processing loads of the processors  507  of the respective measuring units  5   b  and  5   b . Instructions are then transmitted from the CPU  121  of the control device  12  to transport the sample rack L holding the sample container T containing the sample to be re-examined to the sample supplying position  35   c  of the selected measuring unit. 
     The selection information of the measuring unit for performing the re-examination, which has been configured on the measuring unit configuration screen shown in  FIG. 7 , is stored in the transport control information memory  1231  of the control device  12 . The CPU  121  of the control device  12  obtains the information relating to the transport priority of the sample to be re-examined by referencing the selection information of the measuring units stored in the transport control information memory  1231 . 
     The configuration of the measuring unit for performing the re-examination may also be received for each measurement item. In this case, a plurality of measurement items are prestored as determination conditions in the memory  123  of the control device  12 , and the configuration of the selection conditions of the measuring unit are received when re-examination is to be performed for individual measurement items. Since the configuration screen of each measurement item of the measuring unit for performing the re-examination is identical to that of the first embodiment shown in  FIG. 8 , including the configuration content, detailed description is abbreviated. 
     The selection information of the measuring unit for performing the re-examination, which has been configured on the measuring unit configuration screen shown in  FIG. 8 , is stored in the transport control information memory  1231  of the control device  12 . The CPU  121  of the control device  12  obtains the information relating to the transport priority of the sample to be re-examined by referencing the selection information of the measuring units stored in the transport control information memory  1231 . 
     Note that, whether or not re-examination is required may also be determined based on whether or not the obtained measurement data are within a normal range by storing a normal range of normal measurement values in the memory  123  of the control device  12  to be used for determining whether the measurement value of each measurement item is normal. In this case, an item may be provided for receiving the configuration of a normal range for each measurement item in the example of  FIG. 8 . Note that overlooking a sample that requires re-examination can be prevented before the occurrence and needless re-examination can be avoided by suitably configuring a normal range for each measurement item. A normal range for each measurement item of the configuration can be stored in the memory  123  of the control device  12 . 
       FIG. 13  is a flow chart showing the sequence of the re-examination process performed by the CPU  121  of the control device  12  of the analyzer  1  of the third embodiment of the present invention. In  FIG. 13 , the CPU  121  of the control device  12  of the analyzer  1  of the third embodiment determines whether a sample for which an analysis result has been obtained will be re-examined (step S 1301 ). When the CPU  121  determines not to re-examine (step S 1301 : NO), the CPU  121  end the process. 
     When the CPU  121  determines to perform re-examination (step S 1301 : YES), the CPU  121  references the measuring unit selection information stored in the transport control information memory  1231  (step S 1302 ), and specifies the transport priority measuring unit to perform re-examination of the sample requiring re-examination (step S 1303 ). 
     The CPU  121  determines whether the specified measuring unit is the same measuring unit that performed the first examination (step S 1304 ). When the CPU  121  determines that the specified measuring unit is the same measuring unit that performed the first examination (step S 1304 : YES), the CPU  121  transmits instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined back to the sample supplying position  35   c  of the measuring unit that performed the first examination (step S 1305 ). 
     When the CPU  121  determines that the specified measuring unit is not the same measuring unit that performed the first examination (step S 1304 : NO), the CPU  121  transmits instructions to transport the sample rack L holding the sample container T containing the sample to be re-examined to the specified measuring unit (step S 1306 ). 
     According to the third embodiment, the configuration of the measuring unit for performing re-examination of a sample can be optionally received. Therefore, it is possible to receive an explicit specification of the measuring unit that performed the first examination capable of obtaining an analysis result in the shortest time, or a different measuring unit than that which performed the first examination as the measuring unit for performing the re-examination. Accordingly, it is possible to perform the re-examination by the sample using the measuring unit that performed the first examination or using a different measuring unit when the analysis result of a predetermined measurement item is outside the normal range, and when a cause of the abnormality can not be specified. 
     Note that the present invention is not limited to the embodiments described above, and may be variously modified and rearranged insofar as such modification is within the scope of the invention. For example, the transport control device  8  and control device  9  may be singular or plural, or may be integratedly combined. 
     Furthermore, the re-examination order signal may be transmitted to the transport control device  8  when the control device  9  performs a determination as to whether a sample requires re-examination and has determined that the sample requires re-examination. However, the present invention is not limited to this configuration. For example, a host computer connected to the analyzer  1  through the LAN  7  may perform the determination as to whether a sample requires re-examination, and may transmit a re-examination order signal to the transport control device  8  when the host computer has determined that the sample requires re-examination.

Technology Category: 3