JP2016095133A - Automatic analyzer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To discard waste liquid kept in a waste liquid tank without interrupting operation in a facility where an automatic analyzer is continuously operated for 24 hours a day.SOLUTION: An automatic analyzer includes: a means to temporary intercept waste liquid ejection drawn to a waste liquid tank; a means to keep the waste liquid during this period; and a means to discard the waste liquid kept in a waste liquid tank without interrupting operation.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an automatic analyzer that performs qualitative / quantitative analysis of biological samples such as blood and urine, and relates to an automatic analyzer that includes means for holding waste liquid discharged in the analysis operation in a waste liquid tank.

  Automatic analyzers that automatically perform quantitative and qualitative analysis of biological samples such as blood and urine are very popular, especially in large hospitals and clinical laboratories that need to process many patient specimens in a short time. Various automatic analyzers of large, medium and small sizes have been developed.

  These analyzers discharge waste liquid when performing an analysis operation, and the waste liquid may contain infectious substances and the like, and in many cases, is retained in a waste liquid tank.

  In recent years, the high throughput of automatic analyzers and the rapid output of results are required, so in facilities with many patient samples processed in one day, automatic analyzers output measurement results as soon as possible. It is desirable not to stop the apparatus as much as possible.

JP 2009-25174 A JP 2012-21778 A JP 2012-8123 A

  In the conventional apparatus described above, when discharging the waste liquid held in the waste liquid tank, it is necessary to stop the apparatus once so that the waste liquid is not discharged. In order to restart the analysis, it is necessary to restart the analysis after discharging the waste liquid.

  The automatic analyzer performs preparatory operations such as washing the reaction container and measuring the amount of light transmitted through the reaction container before analysis. This preparation operation takes time. Samples put in after the preparatory operation is dispensed immediately after being transported to the analysis unit, so the analysis result is output in the time required for the biochemical reaction. Since it is dispensed, the analysis result is delayed by the time of the preparation operation.

In a facility where the automatic analyzer is continuously operated for 24 hours, an urgent sample may be measured. Therefore, it is desired to optimize the analysis time by the automatic analyzer.
An object of the present invention is to enable disposal of waste liquid held in an essential waste liquid tank in a facility where the apparatus is continuously operated without interrupting operation.

  The present invention relates to an automatic analyzer that is connected to an analysis unit for analyzing a sample and holds waste liquid discharged in the analysis operation in a waste liquid tank, and means for temporarily blocking discharge of the waste liquid discharged to the waste liquid tank And an automatic analyzer having means for holding the waste liquid discharged in the meantime, and having means for discarding the waste liquid held in the waste liquid tank without interrupting the operation operation.

  According to the present invention, it is possible to make it possible to dispose of waste liquid held in an essential waste liquid tank in a facility where the automatic analyzer is operated continuously for 24 hours without interrupting operation. In addition, by eliminating the time zone during which sample analysis is not possible, the measurement waiting time when an emergency sample arrives can be minimized.

It is the schematic showing the example of 1 structure of the automatic analyzer to which this invention is applied. It is the schematic showing the system configuration example which is one Example of this invention. It is explanatory drawing which showed the waste-liquid buffer tank installation which is one Example of this invention. It is a monitoring flowchart which is one Example of this invention. It is a waste liquid level information screen which is one Example of the present invention. It is explanatory drawing which showed the waste-liquid buffer tank installation which is one Example of this invention. It is a monitoring flowchart which is one Example of this invention. It is a waste liquid tank switching screen which is one Example of the present invention. It is explanatory drawing which showed the some waste liquid tank installation which is one Example of this invention. It is a monitoring flowchart which is one Example of this invention. It is a waste liquid level information screen which is one Example of the present invention.

  Hereinafter, the configuration and operation of an automatic analyzer according to an embodiment of the present invention will be described with reference to FIGS.

  First, an example of an automatic analyzer to which the present invention is applied will be described with reference to FIG. FIG. 1 is a diagram in which a conceptual diagram of a control system is added to the top layout of the main part of the automatic analyzer. The automatic analyzer to which the present invention is directed is provided with a mechanism for collecting a predetermined amount of a liquid such as a sample or a reagent using a dispensing nozzle. In the following description, an automatic analyzer for clinical tests that analyzes biological samples such as blood and urine will be described as an example. Is not to be done.

  The automatic analyzer 1 is arranged concentrically with the sample disk 2 and the sample container 3 arranged concentrically, the reaction disk 4 and the reaction container 5 arranged concentrically, the sample dispensing mechanism 6 and the reagent disk 7. Reagent container 8 containing various reagents, reagent dispensing mechanism 9, stirring mechanism 10, light source 11, photometer (multi-wavelength photometer) 12, A / D converter 13, reaction container cleaning mechanism 14, dispensing nozzle A cleaning mechanism 15 is provided.

  The analysis by the automatic analyzer 1 is performed in the following order. First, the sample dispensing mechanism 6 dispenses the sample to be analyzed from the sample container 3 to the reaction container 5. Next, the reagent dispensing mechanism 9 dispenses a reagent used for analysis from the reagent container 8 to the reaction container 5. Subsequently, the mixed solution is stirred by the stirring mechanism 10. Light generated from the light source 11 and transmitted through the reaction vessel 5 containing the mixed solution is detected and measured by a photometer (multi-wavelength photometer) 12 and transmitted to the interface 17 via the A / D converter 13. The computer 18 includes a control unit, and the measurement result obtained as a result of the calculation by the control unit is stored in the storage unit 19 and is output to the information device, for example, displayed on the display unit 20. The dispensing nozzle cleaning mechanism 15 cleans the tip of the dispensing nozzle each time the sample dispensing mechanism 6 and the reagent dispensing mechanism 9 dispense a sample or reagent. The reaction vessel 5 after the reaction is washed by the reaction vessel washing mechanism 14 and repeatedly used for the next reaction. The operation mechanisms of these analyzers are all controlled by a control unit included in the computer 18 via the communication means 16 and the interface 17.

  In calculating the above measurement results, a calibration curve is used. The calibration curve data is measured in advance before measuring a sample having a predetermined item of unknown concentration. Calibration curve data can be created by using a standard solution with a predetermined concentration of a predetermined item and determining the relationship between the concentration and information detected by the photometer. Based on the obtained relationship, the concentration of the predetermined item can be obtained from the information detected by the photometer for the sample having the unknown concentration.

  Next, an automatic analyzer connected to a waste liquid tank will be described with reference to FIG.

  The automatic analyzer according to the present embodiment includes a sample input unit 201, a sample storage unit 202, transport lines 203 and 204, a sample standby unit 205, analysis units 206 and 207, and an overall management computer 208. Yes.

  The sample rack loading unit 201 is a portion for loading a sample rack on which a container containing a plurality of sample racks each holding a plurality of samples (samples) is placed. The sample holder is not limited to the sample rack, and may be a sample holder that holds one sample. The analysis units 206 and 207 are arranged along the transfer line 204 and are detachably connected to the transfer line 204. The number of analysis units may be arbitrary, and in this embodiment, two cases are shown.

  In the present embodiment, the case of a biochemical analysis unit is shown. However, for example, it may be configured by a combination with a gene analysis unit or an immune analysis unit.

  The transport line 204 transports the sample rack from the sample rack input unit 201 to a predetermined analysis unit among the analysis units 206 and 207. Further, the transport line 204 transports the sample rack holding the sample that has been analyzed by the analysis units 206 and 207 so as to be stored in the sample rack collection unit 202.

  In addition, a buffer 205 installed in the transport line 204 that transports the rack on which the sample is loaded stores arbitrary racks transported by the transport lines 203 and 204. One rack may be stored, or a plurality of racks may be stored. The rack can be supplied again to the analysis unit or the sample rack recovery unit 202 at an arbitrary timing. Other buffer forms include, for example, one in which a plurality of slots are allocated to a circular base and the rack can be held. However, it is possible to physically store and supply the rack randomly. Any form is acceptable.

  The analysis units 206 and 207 include analysis unit computers 209 and 210 that perform control for necessary processing in each analysis unit. The sample rack input unit 201 includes a computer 211 that performs necessary control in the sample rack input unit 201, the transfer lines 203 and 204, the buffer 205, and the sample rack collection unit 202.

  The analysis unit computers 209, 210, and 211 are connected to the overall management computer 208. An operation unit 212 and a display unit 213 each having an input / output device for inputting necessary information are further connected to the computer 208.

  The computer 208 manages the state of the entire automatic analyzer, and notifies the analysis unit computers 209, 210, and 211 of analysis start requests and analysis end requests instructed from the operation unit 212.

  The computer 208 is connected to a waste liquid tank 221 that holds the waste liquid discharged from the analysis units 206 and 207, and is monitored. The number of waste liquid tanks may be arbitrary, and in this embodiment, the case of one is shown. One unit may be connected to each analysis unit, and monitoring by the analysis unit computers 209 and 210 may be used.

  Next, the first implementation method of the present invention will be described with reference to FIGS.

  FIG. 3 shows an example in which a drain cock is used as means for blocking drainage to the waste liquid tank.

  Waste liquid from the automatic analyzer passes through the waste liquid buffer tank 302 via the pipe 301 and is discharged to the waste liquid tank 304.

  Connected to the waste liquid tank 304 is a water level sensor 305 capable of monitoring the water level of the waste liquid held in the waste liquid tank.

  Based on the information of the water level sensor 305, when it is determined that the waste liquid tank 304 has exceeded the warning water level, a warning is displayed on the display unit 20 to alert the operator to discard the waste liquid in the waste liquid tank. To do.

  Following this warning, the operator closes the drain cock 303, temporarily shuts off the waste liquid discharge to the waste liquid tank 304, and discards the waste liquid in the waste liquid tank 304.

  Waste liquid discharged during this operation is temporarily held in the waste buffer tank 302.

  After the disposal is completed, the waste liquid tank 304 is reinstalled, and the drain cock 303 is opened again, so that the waste liquid temporarily held in the waste liquid buffer tank 302 is discharged to the waste liquid tank 304.

  The waste liquid buffer tank 302 is connected to a water level sensor 306 capable of monitoring the water level of the waste liquid held in the waste liquid buffer tank.

  When it is determined that the waste liquid tank 306 has exceeded the warning water level based on the information of the water level sensor 306, a warning is displayed on the display unit 20 to alert the operator to discard the waste liquid in the waste liquid tank. To do.

  Further, when it is determined that the liquid level of the waste liquid buffer tank is full, the operation is automatically stopped to prevent the waste liquid from overflowing from the tank, and the abnormality is displayed on the display unit 20 as an alarm.

  Next, a waste liquid monitoring flowchart for the automatic analyzer connected to the waste liquid buffer tank will be described with reference to FIG.

  In step 401, the current waste liquid discharge destination is determined, and the processing in step 402 or the processing in step 403 is selected and executed.

  Step 402 is a waste liquid tank monitoring process. Based on the water level information obtained from the water level sensor 305, it is determined in step 411 whether or not the liquid level is above the limit level of the waste liquid tank. The display unit 20 displays a warning that the waste liquid tank is full.

  If it is determined in step 411 that the liquid level is below the limit level of the waste liquid tank, it is further determined in step 413 whether the liquid level is above the warning level of the waste liquid tank. A warning is displayed indicating that the warning water level is exceeded.

  Step 403 is a waste liquid buffer tank monitoring process. Based on the water level information obtained from the water level sensor 306, it is determined in step 421 whether the water level is above the limit level of the waste liquid buffer tank. At 422, a warning is displayed on the display unit 20 that the waste buffer tank is full.

  If it is determined in step 421 that the liquid level is below the limit level of the waste liquid buffer tank, it is further determined in step 423 whether the liquid level is above the warning level of the waste liquid buffer tank. A warning is displayed that the buffer tank is above the warning water level.

  FIG. 5 is a display example in which the water level information in the waste liquid tank and the waste liquid buffer tank is displayed on the screen.

  201 of the waste liquid level information screen represents the waste liquid level in the waste liquid buffer tank, and 202 represents the waste liquid level in the waste liquid tank.

  Reference numerals 203 and 204 denote the current level of the waste liquid buffer tank and the waste liquid tank in% relative to the water level that can be held in each tank.

  FIG. 6 shows an example in which a solenoid valve is used as a means for blocking drainage to the waste liquid tank.

  If it is determined that the waste liquid tank 604 has exceeded the warning water level based on the information of the water level sensor 605, a warning is displayed on the display unit 20 to alert the operator to discard the waste liquid in the waste liquid tank. To do.

  Further, when the waste liquid tank water level exceeds the limit water level, the electromagnetic valve 603 is closed, the waste liquid discharge to the waste liquid tank 604 is temporarily interrupted, and the waste liquid in the waste liquid tank 304 is discarded.

  By discharging the waste liquid held in the waste liquid tank 604, when the water level information using the water level sensor 605 falls below the warning water level, the electromagnetic valve 603 is opened and the waste liquid temporarily held in the waste liquid buffer tank 602. Is discharged to the waste liquid tank 604.

  Other means are the same as described with reference to FIG.

  FIG. 7 is a waste liquid monitoring flowchart in the case where a solenoid valve is used as means for blocking the drainage to the waste liquid tank.

  Step 702 is a waste liquid tank monitoring process. Based on the water level information obtained from the water level sensor 605, it is determined in step 711 whether or not the liquid level is above the limit level of the waste liquid tank. The display unit 20 displays a warning that the waste liquid tank is full.

  Further, in step 713, the electromagnetic valve 603 is closed, and the discharge to the waste liquid tank is temporarily blocked.

  If it is determined in step 711 that the liquid level is lower than the limit level of the waste liquid tank, it is further determined in step 714 whether the liquid level is higher than the warning level of the waste liquid tank. A warning is displayed indicating that the warning water level is exceeded.

  If it is determined in step 714 that the liquid level is below the warning level of the waste liquid tank, the electromagnetic valve 603 is opened in step 715, and the waste liquid in the waste liquid buffer tank 602 that temporarily holds the waste liquid is discharged to the body fluid tank 604.

  Other processes are the same as those in FIG.

  FIG. 8 shows an example in which an input from the display unit 20 is used as means for blocking discharge to the waste liquid tank.

  By depressing a tank replacement button 801 in the waste liquid level information screen, the electromagnetic valve 603 is closed and the discharge to the waste liquid tank is temporarily blocked.

  By using this means, it becomes possible for the operator to discard the waste liquid in the waste liquid tank in advance before the waste liquid tank becomes full.

  Next, a second implementation method of the present invention will be described with reference to FIG.

  Waste liquid from the automatic analyzer is discharged to the waste liquid tank 911 or the waste liquid tank 921 via the pipe 901.

  The solenoid valve 902 selects which waste liquid tank is discharged.

  Connected to the waste liquid tanks 911 and 921 are water level sensors 912 and 922 that can monitor the water level of the waste liquid held in the waste liquid tank, respectively.

  When it is determined that the waste liquid tanks 911 and 921 have exceeded the warning water level based on the information of the water level sensor, a warning is displayed on the display unit 20 and the operator discards the waste liquid in the waste liquid tank. Arouse.

  Further, when it is determined that the waste liquid tank has exceeded the limit water level, the waste liquid is discharged to the other waste liquid tank using the electromagnetic valve 902.

  At this time, it is possible to determine which waste liquid tank should be discarded using the LED warning lamps 913 and 923.

  The number of connected waste liquid tanks may be arbitrary, and in this embodiment, two cases are shown.

  Also, in the means for selecting a plurality of waste liquid tanks, the solenoid valve is used in the present embodiment, but a waste liquid tank selection method using a switching cock may be used.

  Next, a waste liquid monitoring flowchart will be described with reference to FIG.

  In step 1001, it is determined whether the water level is above the limit water level based on the water level information obtained from the water level sensor 912 or 922 connected to the waste liquid tank that is the current discharge destination. If it is determined that the water level is equal to or higher than the limit water level, a warning is displayed on the display unit 20 that the waste liquid tank is full in step 1002.

  Further, in step 1003, based on the water level information obtained from the water level sensor of the other waste liquid tank, it is determined whether the other waste liquid tank is usable.

  When it is determined that the other waste liquid tank can be used, the electromagnetic valve 902 is switched in step 1004 to switch the waste liquid tank for discharging the waste liquid to the other.

  In step 1005, an LED warning lamp 913 or 923 is displayed as a warning so that a waste liquid tank that needs to be disposed of can be selected.

  When it is determined that the other waste liquid tank cannot be used, a warning is displayed in step 1006 that there is no usable waste liquid tank on the display unit 20.

  If it is determined in step 1001 that the water level is below the critical water level, it is further determined in step 1011 whether the water level in the waste liquid tank is equal to or higher than the warning water level. A warning is displayed on the display unit 20 that the waste liquid tank is full.

  FIG. 11 is a display example of displaying a plurality of waste water tank water level information on the screen.

  The waste liquid level information screens 1101 and 1102 represent the water levels of the connected waste liquid tanks.

  Further, 1103 and 1104 represent the current water level of the waste liquid tank in% relative to the water level that can be held in each tank.

  In addition, the use status of the waste liquid tank is displayed in 1105 and 1106, the waste liquid tank from which the waste liquid is currently discharged can be confirmed, and the waste liquid tank that needs to discharge the waste liquid can be selected.

  Furthermore, by pressing 1105 or 1106, it is possible to switch the discharge of the waste liquid to the other waste liquid tank, and it is also possible to discharge the waste liquid in the waste liquid tank in advance before the waste liquid tank becomes full. Become.

  As described above, according to the present embodiment, the waste liquid retained in the waste liquid tank can be discarded without interrupting the operation, and the time zone during which sample analysis cannot be performed can be eliminated.

1 automatic analyzer 2 sample disk 3 sample container 4 reaction disk 5 reaction container 6 sample dispensing mechanism 7 reagent disk 8 reagent container 9 reagent dispensing mechanism 10 stirring mechanism 11 light source 12 photometer (multi-wavelength photometer)
13 A / D converter 14 Reaction vessel cleaning mechanism 15 Dispensing nozzle cleaning mechanism 16 Communication means 17 Interface 18 Computer 19 Storage means 20 Display section 21 Parent screen 22 Subscreen 23 Standard solution measurement status screen tab 24 Standard solution measurement status for each item Display area 25 Standard solution measurement status display area for specified items

Claims (7)

  In an automatic analyzer connected to an analysis unit for analyzing a sample and holding waste liquid discharged in the analysis operation in the waste liquid tank, means for temporarily blocking waste liquid discharge to the waste liquid tank, An automatic analyzer comprising: means for holding waste liquid discharged into the waste liquid, and means for discarding waste liquid held in the waste liquid tank without interrupting operation. The automatic analyzer according to claim 1, wherein
The automatic analyzer is characterized in that the means for holding the waste liquid is a waste liquid buffer tank in a pipe connected to the waste liquid tank. The automatic analyzer according to claim 2,
An automatic analyzer comprising: means for monitoring a waste liquid level in the waste liquid buffer tank; and a function of giving a warning to an operator according to the waste liquid level. The automatic analyzer according to claim 2,
An automatic analyzer comprising means for outputting the waste liquid tank and water level information in the waste liquid buffer tank to the outside. The automatic analyzer according to claim 1, wherein
A function to connect multiple waste liquid tanks, select one of them, discharge the waste liquid, and select the waste liquid tank that can hold other waste liquids when the waste liquid tank is full, and use it by switching An automatic analyzer characterized by comprising. The automatic analyzer according to claim 5, wherein
An automatic analyzer comprising means for outputting water level information in the waste liquid tank to the outside. The automatic analyzer according to claim 5, wherein
An automatic analyzer comprising means for outputting information on one waste liquid tank in use and the other replaceable waste liquid tank to the outside.