JP3681885B2 - Biochemical analyzer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a biochemical analyzer for obtaining a substance concentration of a predetermined biochemical substance in a sample solution using a chemical analysis element on which a sample solution such as blood or urine is spotted.
[0002]
[Prior art]
Conventionally, dry-type chemical analysis elements that can quantitatively analyze specific chemical components or formed components contained in sample liquids by simply spotting and supplying sample liquid droplets have been put into practical use. Yes. In addition, in order to quantitatively analyze chemical components in a sample solution using such a chemical analysis element, after the sample solution is spotted on the chemical analysis element, it is placed in an incubator. For a measurement that includes a wavelength selected in advance by a combination of a predetermined biochemical substance in the sample solution and a reagent contained in the chemical analysis element after holding at a constant temperature (incubation) for a predetermined time to cause a color reaction (dye formation reaction) The chemical analysis element is irradiated with irradiation light and its optical density is measured. From this optical density, a sample is drawn using a calibration curve representing the correspondence between the optical density determined in advance and the substance concentration of a predetermined biochemical substance. A biochemical analyzer configured to obtain the concentration of a predetermined biochemical substance in the liquid is used.
[0003]
In this biochemical analyzer, the chemical analysis elements are sequentially transported to the incubator, and the measured chemical analysis elements are taken out from the incubator for disposal. As seen in Japanese Patent Publication No. 61-26864, U.S. Pat.No. 4,296,069, etc., the chemical analysis element is carried into the disc-type incubator from the outer periphery side, and the chemical analysis element for which the measurement has been completed It is provided to be carried out and discarded by pushing it out from the side or taking it out from the outer peripheral side.
[0004]
In addition, the chemical analysis element on which the sample solution is spotted is inserted into the storage part of the rotary incubator having a storage part for storing a plurality of chemical analysis elements one by one by means of transport means. Perform a predetermined incubation in the storage unit, measure the color reaction of the chemical analysis element from the bottom of the storage unit, transport the chemical analysis element that has been measured further toward the center of the incubator by the transport means, and place it in the central part of the incubator. There is also known a biochemical analyzer that is dropped into an open disposal hole (Japanese Patent Laid-Open No. 6-66818).
[0005]
On the other hand, in the biochemical analyzer as described above, in order to analyze a biochemical substance contained in blood, whole blood is separated into plasma or serum and blood cells by a centrifugal separator, and the separated plasma or serum is used. In most cases, analysis is performed as a sample solution.
[0006]
[Problems to be solved by the invention]
When blood is analyzed by the biochemical analyzer as described above, it may be necessary to analyze blood immediately as in an emergency patient. However, in order to obtain plasma or serum for analyzing blood components, it is necessary to separate the blood with a centrifugal separator. could not.
[0007]
In view of the above circumstances, an object of the present invention is to provide a biochemical analyzer that can quickly perform biochemical analysis of blood by quickly separating blood into plasma or serum.
[0008]
[Means for Solving the Problems]
The biochemical analyzer according to the present invention is a biochemical analyzer for obtaining a concentration of a predetermined biochemical substance in the sample solution using a chemical analysis element on which the sample solution is spotted.
A filter that filters whole blood to obtain a filtrate as a sample liquid, a holder that holds the filter and has a blood inlet and a filtrate outlet, and a filter that is provided on the filtrate outlet side and receives the filtrate A blood filtration unit having a liquid receiving tank;
A spotting means for spotting the filtrate in the filtrate receiving tank on the chemical analysis element and a negative pressure acting on the holder from the filtrate outlet side are provided detachably on the filtrate outlet side. And a spotting arm having suction means.
[0009]
The biochemical analyzer according to the present invention further includes a receiving unit that receives the filtrate from the filtrate receiving tank, and further includes a dilution unit that mixes the diluent in the receiving unit to dilute the filtrate in the receiving unit. It is preferable to provide.
[0010]
【The invention's effect】
According to the biochemical analyzer of the present invention, the plasma or serum in the blood is filtered by attaching a suction means provided on the spotting arm to the blood filtration unit and applying a negative pressure from the filtrate outlet side. Plasma or serum that has been filtered and separated from the blood in the filtrate receiving tank is filled with the filtrate. Then, the filtrate in the filtrate receiving tank is spotted on the chemical analysis element by the spotting means, and the concentration of the biochemical substance in the sample liquid is obtained using this chemical analysis element. Therefore, the plasma or serum can be separated from the blood simply by aspiration by the aspirating means, and the collected blood can be separated and analyzed only through the blood filtration unit. Compared to the case of using a separation device, plasma or serum can be separated and analyzed from blood in a short period of time, thereby responding to urgent need for biochemical analysis of blood Can do.
[0011]
Further, by providing the spotting arm with the spotting means and the suction means, a mechanism for driving the suction means can be omitted, and the configuration of the apparatus can be simplified.
[0012]
Furthermore, by providing a dilution unit for diluting the filtrate in the biochemical analyzer according to the present invention, the filtrate that needs to be diluted can be immediately analyzed.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a schematic plan configuration of a biochemical analyzer according to an embodiment of the present invention.
[0014]
The biochemical analyzer 10 includes a blood filtration device 5 that separates plasma from blood, a slide standby unit 12 that accommodates unused chemical analysis slides 11, and plasma (whole blood, serum, urine, etc.) (It will be described only in the case of plasma in the present embodiment), but it includes a spotting part 13 for spotting a sample solution and an incubator 14 for storing the chemical analysis slide 11 and keeping the temperature constant for a predetermined time. Then, the chemical analysis slide 11 is sequentially transferred from the slide standby unit 12 to the spotting unit 13, and the chemical analysis slide 11 located in the spotting unit 13 is moved to the tip of the spotting nozzle 91 of the spotting means 17 (sampler). After the nozzle tip 25 (see FIG. 6) is mounted, the sample liquid (plasma) is sucked into the nozzle tip 25 from the sample storage portion 16 and spotted on the slide 11 and then spotted. The chemical analysis slide 11 is transferred by the transport means 15. Then, the degree of coloration (reflection optical density) of the chemical analysis slide 11 inserted in the storage portion 55 of the incubator 14 and kept at a constant temperature by the incubator 14 is measured by the photometric head 27 of the measuring means 18, and the chemical analysis slide after the measurement is further performed. 11 is dropped and discharged into the disposal hole 56 on the center side of the incubator 14 by the conveying means 15. The spotting means 17 is provided with syringe means 19 for sucking and discharging the sample liquid by the nozzle tip 25 and suction-filtering plasma from blood as described later, and the used nozzle tip 25 is located in the vicinity of the incubator 14. It is removed from the spotting nozzle 91 at the disposed chip extraction portion 20 and dropped down and discarded.
[0015]
Here, FIG. 9 shows a configuration of the chemical analysis slide 11 used for measuring the degree of coloration of plasma. As shown in FIG. 9, the chemical analysis slide 11 has a reagent layer disposed in a rectangular mount, and a spotted hole 11a is formed on the surface of the mount. Plasma is spotted in the spotting hole 11a as described later. Further, a bar code for specifying an inspection item or the like is attached to the back surface of the chemical analysis slide 11.
[0016]
The structure of each part will be described. First, as shown in FIG. 2, the blood filtration device 5 includes a blood filtration unit 9 attached to the opening of the blood collection tube 7 accommodated in the sample accommodation part 16, and a blood filtration unit 9. It comprises suction means 2 that is connected to a constituent holder 1 and applies a negative pressure for separating plasma from blood. The holder 1 includes a plastic holder main body 1A and a lid 1B. The holder body 1A includes an insertion portion 1a inserted into the blood collection tube, a filter holding portion 1b into which a filter 3 made of glass fiber is inserted, and a flange portion 1c joined to the lid 1B by ultrasonic welding or the like. Become. The lid 1B includes a flange portion 1d joined to the holder body 1A, a cup 1e for holding plasma filtered by the filter 3, and a nozzle-like supply port 1f for supplying plasma from the filter 3 to the cup 1e. Consists of.
[0017]
The suction means 2 is attached to a spotting arm 88 of spotting means 17 described later. A suction cup portion 2b that comes into contact with the lid 1B of the holder 1 is provided on the distal end side of the suction means 2, and this suction cup portion 2b is connected to a negative pressure supply portion 2c connected to a syringe means 19 described later. Further, the negative pressure supply part 2c is provided with a release valve for releasing the negative pressure from the syringe means 19. Further, a liquid level detection sensor 2d for detecting the level of plasma supplied to the cup 1e and preventing the plasma from overflowing from the cup 1e is provided in the suction cup 2b. The rotational drive of the spotting arm 88 will be described later.
[0018]
Then, when separating plasma from blood, as shown in FIG. 3, the insertion portion 1a of the holder 1 is inserted into the blood collection tube 7 accommodated in the sample accommodation portion 16, and the spotting arm 88 is rotated for suction. The suction cup portion 2b of the means 2 is opposed to the holder 1, and the spotting arm 88 is lowered to bring the lid 1B of the holder 1 and the suction cup portion 2b into contact with each other. Next, the syringe means 19 is driven to apply a negative pressure to the space formed between the lid 1B and the suction cup part 2b. Thereby, the whole blood in the blood collection tube 7 is sucked up from the insertion portion 1a, filtered by the filter 3, and plasma is supplied to the cup 1e through the nozzle supply port 1f.
[0019]
The liquid level detection sensor 2d is a sensor that irradiates the liquid level of plasma supplied to the cup 1e with light and optically detects the reflected light. The plasma level is substantially the same as the height of the cup 1e. Sometimes set to output maximum signal value. Therefore, when the maximum signal value is output from the liquid level detection sensor 2d, the release valve of the negative pressure supply unit 2c is released to stop blood suction. Thereafter, the spotting arm 88 is raised and moved to the original position (position shown in FIG. 1), and the filtration is finished.
[0020]
Next, as shown in FIG. 4, the conveying means 15 includes a conveying table 30 that extends linearly toward the center of the incubator 14, and a front and rear end leg portion 30a having a flat plate-like base. The slide stand 12 is disposed at a substantially central portion of the carriage 31, and the spotting portion 13 is disposed on the incubator 14 side thereof.
[0021]
The slide standby section 12 is formed with a slide guide 32 for holding the chemical analysis slide 11, and a plurality of unused chemical analysis slides 11 are usually stacked and held on the slide guide 32. The slide guide 32 is mounted in the recess of the transport table 30 so that the lowermost chemical analysis slide 11 is positioned at the same height as the transport surface of the transport table 30, and one sheet is provided on the front surface side of the lower end. An opening 32a through which only the chemical analysis slide 11 can pass is formed. In addition, an opening into which a later-described insertion member can be inserted is formed on the rear surface side, and a groove 32b communicating with a later-described slit 30b formed in the transport table 30 is formed on the bottom surface. Note that a cartridge containing a plurality of stacked chemical analysis slides 11 may be set in the slide guide 32.
[0022]
A slide presser 33 having a circular opening 33a is installed in the spotting part 13 in front of the slide standby part 12, and this slide presser 33 is slightly moved up and down in a cover 34 fixed to the upper side of the transport base 30. An opening 35a for spotting is also formed in the glass plate 35 which is accommodated and fixed above the cover 34. Further, a bar code reader 130 (see FIG. 1) for reading a bar code provided on the chemical analysis slide 11 is attached to the spotting unit 13. The bar code reader 130 is provided to specify inspection items and the like and to detect the transport direction (front and back, front and back) of the chemical analysis slide 11.
[0023]
The chemical analysis slide 11 is transported by the forward movement of the plate-like insertion member 36 placed on the transport base 30. That is, a slit 30b extending in the front-rear direction is formed at the center of the transport base 30, and the insertion member 36 is slidably mounted on the slit 30b, and blocks from below through the slit 30b at the bottom end of the insertion member 36. 37 is fixed, and the block 37 is slidable in the front-rear direction along the slit 30b. In addition, an auxiliary plate 38 for pressing the insertion member 36 is disposed on the carriage 30 at a position behind the slide standby unit 12 by the slide guide 32, and the auxiliary plate 38 is held in the cover 39 so as to be slightly movable up and down. Has been.
[0024]
In addition, a slider 40 is attached to the lower part of the block 37, and the slider 40 is supported by a guide rod 41 disposed along the transport table 30 so as to be slidable in the front-rear direction. Further, a part of a belt 44 wound around pulleys 42 and 43 disposed before and after the conveyance table 30 is fixed to the slider 40. The rear pulley 43 is rotationally driven by the transport motor 45, and the insertion member 36 is moved in the front-rear direction by a block 37 that moves integrally with the slider 40. The chemical analysis slide at the lower end portion of the slide guide 32 is driven by the distal end portion thereof. 11, the chemical analysis slide 11 is conveyed from the spotting part 13 to the incubator 14 in a straight line.
[0025]
The chemical analysis slide 11 at the lower end of the slide guide 32 is transported to the spotting unit 13 by driving the transport motor 45, and the chemical analysis slide 11 on which the sample solution is spotted is further inserted into the storage unit 55 of the incubator 14 for further measurement. The drive control of the transport motor 45 is performed so that the subsequent chemical analysis slide 11 is transported to the disposal hole 56 at the center of the incubator 14.
[0026]
Next, as shown in FIG. 5, the incubator 14 has a disk-like rotating member 50 rotatably supported with respect to the bearing portion 53 via a bearing 52 by a rotating cylinder 51 in the lower center, as shown in FIG. 5. An upper member 54 is disposed on the rotating member 50. The bottom surface of the upper member 54 is flat, and a plurality of (six in the case of FIG. 1) concave portions are formed on the upper surface of the rotating member 50 at predetermined intervals on the circumference, and a slit-like space is formed between the members 51 and 54. A storage portion 55 is formed, and the height of the bottom surface of the storage portion 55 is the same as the height of the transfer surface of the transfer stand 30 of the transfer means 15, and approaches the front end portion of the transfer stand 30 and the outer periphery of the rotating member 50 The part is located.
[0027]
Further, the inner hole of the rotating cylinder 51 is formed in the disposal hole 56 of the chemical analysis slide 11 after the measurement, and the diameter of the disposal hole 56 is set to a dimension through which the chemical analysis slide 11 can pass, and the rotation member An opening 50 a communicating with the discard hole 56 is formed in the central portion of 50. The central portion of the storage portion 55 communicates with the opening 50a on the central side at the same height as the storage portion 55. When the chemical analysis slide 11 located in the storage portion 55 moves to the central side as it is, it enters the disposal hole 56. Configured to fall.
[0028]
The upper member 54 is provided with a heating means (not shown), and the chemical analysis slide 11 in the storage unit 55 is maintained at a constant temperature by adjusting the temperature thereof, while the upper member 54 has the chemical analysis slide 11 corresponding to the storage unit 55. A presser member 57 that prevents the sample liquid from evaporating by pressing the mount from above is provided. A cover 58 is disposed on the upper surface of the upper member 54, while the incubator 14 is covered with an upper cover 59 on the upper side and the side, and a bottom portion is covered with a lower cover 60 to block light. Note that the heating means heats the chemical analysis slide 11 in the storage unit 55 in the incubator 14 to 37 ± 0.2 ° C. in the portion for measuring the coloration degree of the chemical analysis slide 11.
[0029]
Further, a photometric opening 55a is formed at the center of the bottom surface of each storage portion 55 for storing the chemical analysis slide 11 of the rotating member 50, and the chemical by the photometric head 27 disposed at the position shown in FIG. 1 through this opening 55a. The reflection optical density of the analysis slide 11 is measured.
[0030]
Here, the rotational drive of the incubator 14 is performed by winding a timing belt (not shown) around the outer peripheral portion of the rotating cylinder 51 that supports the rotating member 50, and this timing belt is driven by a drive pulley (both not shown) of the drive motor. The reciprocating rotational drive of the rotary member 50 is performed by forward / reverse rotational drive of the drive motor. The rotation operation of the incubator 14 is performed by first detecting the density of the white reference plate and then detecting the density of the black reference plate with respect to the photometric head 27 arranged below the predetermined rotation position of the incubator 14. After the calibration, the optical density of the color reaction of the chemical analysis slide 11 inserted in the storage unit 55 is sequentially measured, and after this series of measurements, it is rotated backward to return to the reference position. In order to measure the slide 11, the reciprocating rotation is controlled within a predetermined angle range.
[0031]
Further, a recovery box 70 for recovering the chemical analysis slide 11 after the measurement is disposed below the incubator 14. The collection box 70 is formed below the disposal hole 56 at the center of the rotary cylinder 51, and a storage chamber 71 is formed. The collection box 70 is arranged in the incubator 14 in relation to the arrangement of other various devices. It is widely formed on one side with respect to the center point. In addition, an inclined portion 72 in which a nozzle tip 25 to be replaced for each sample solution in the spotting means 17 described later is dropped is formed at a corner portion of the storage chamber 71. The inclined portion 72 is located below the tip extracting portion 20 where the nozzle tip 25 is dropped, and the bottom surface of the inclined portion 72 guides the falling nozzle tip 25 to the center side of the containing chamber 71. It is formed on an inclined surface (20-45 °) that lowers the 71 side.
[0032]
In addition, a protrusion 73 is erected on the bottom of the storage chamber 71 at a position shifted from the center of the disposal hole 56 to the side opposite to the widened portion of the storage chamber 71. This protrusion 73 has a tip formed in a spherical shape or a needle shape, and has a function of contacting the chemical analysis slide 11 falling from the disposal hole 56 and changing the falling direction to disperse.
[0033]
Next, as shown in FIG. 6, the sample storage section 16 has a cross-sectional front structure, as shown in FIG. 6, a reference liquid chip holding section 16a, an electrolyte sample chip holding section 16b, a reference liquid storage pipe 16c, and a diluent chip holding section 16d. , A diluent cup 16e, a mixing cup 16f, a blood collection tube holder 16g and a sample tip holder 16h are formed, a reference solution tip holder 16a, an electrolyte sample tip holder 16b, and a diluent tip holder The reference liquid chip 25a, the electrolyte sample chip 25b, the diluting solution chip 25d, and the sample chip 25h are held in the unit 16d and the sample chip holding unit 16h, respectively. Further, a reference liquid chip holding part 16a, an electrolyte specimen chip 16b, a reference liquid storage tube 16c, a diluent tip holding part 16d, a diluent cup 16e, a mixing cup 16f, a blood collection tube holding part 16g, and a specimen chip holding part 16h is set so as to be positioned on the turning trajectory of the spotting nozzle 91a accompanying the turning of the spotting arm 88 of the spotting means 17, which will be described later, as shown in FIG. The sample storage unit 16 is a consumable as a whole, and the entire sample storage unit 16 can be replaced with the biochemical analyzer according to the present embodiment. In the present embodiment, the reference liquid chip 25a and the electrolyte sample chip 25h are not used.
[0034]
Next, as shown in FIG. 7, the spotting means 17 has a flange member 83 rotatably attached to a support member 80 installed on the base 31 via a bearing (not shown) as shown in FIG. 7. ing. Guide rods 84 and 84 are erected on both sides of the outer peripheral side of the flange member 83, and the upper ends of the guide rods 84 and 84 on both sides are fixed to the connecting member 85, so that both guide rods 84 and 84 are in the vertical direction. Are arranged in parallel with each other. Further, a feed screw 86 is arranged in the vertical direction at the rotation center portion of the connecting member 85, the upper end of the feed screw 86 is rotatably supported by the connecting member 85, and the lower end portion is freely rotatable at the center portion of the flange member 83. Further, the front end portion protrudes from the flange member 83, and the pulley 87 is fixed. Further, the base end portion of the spotting arm 88 is supported by the guide rods 84 and 84 on both sides so as to be movable up and down, and a sleeve 89 into which the guide rods 84 and 84 are inserted is interposed in the spotting arm 88 of the supporting portion. Has been. Further, the lead screw 86 penetrates the spotting arm 88, and a nut member 90 that is screwed to the lead screw 86 is provided in the penetrating portion so that the spotting arm 88 moves up and down according to the rotation of the lead screw 86. It is configured.
[0035]
Further, as shown in FIG. 8 which is an enlarged view of the direction A in FIG. 7, a spotting nozzle 91a for sucking and discharging the sample liquid penetrating in the vertical direction is provided at the tip of the spotting arm 88 and the above-mentioned The suction means 2 is disposed. The shaft portion of the spotting nozzle 91a is slidably inserted into the spotting arm 88 and is urged downward by a spring 92a. In addition, pipette-shaped nozzle tips 25a, 25b, 25d, and 25h (represented by 25 below) are detachably attached to the tip of the spotting nozzle 91a. 25 is set in the sample storage portion 16, and is fitted and held at the tip of the spotting nozzle 91a by the downward movement of the spotting arm 88. After use, the nozzle tip is inserted into the engagement groove 20a of the tip extraction portion 20. The fitting is disengaged by the upward movement of the spotting arm 88 with the upper end of 25 engaged, and is dropped from the opening 20b of the chip extracting portion 20 into the lower collection box 70 and discarded.
[0036]
In the turning operation of the spotting arm 88, the timing belt 94 is engaged with the outer peripheral portion of the flange member 83, and this timing belt 94 is wound around the drive pulley of the turning motor (not shown). It is swung to a predetermined position by reverse rotation drive control. In order to move the landing arm 88 up and down, that is, to rotate the feed screw 86, a timing belt 99 is wound between the pulley 87 at the lower end and the driving pulley of the lifting motor, and the lifting and lowering motor rotates forward and backward. It is moved to a predetermined height by the drive control.
[0037]
Next, a mechanism for sucking and discharging the sample liquid into the nozzle chip 25 and a mechanism for supplying a negative pressure to the suction means 2 will be described. An air passage 101a opening at the tip is formed in the center of the spotting nozzle 91a, and an air pipe 110a is connected to the upper end portion of the air passage 101a. The other end of the air pipe 110a is connected to the right end portion (see FIG. 1) of the syringe 102 of the syringe means 19. The negative pressure supply unit 2c of the suction means 2 is also connected to the right end portion of the syringe 102. The syringe 102 is a syringe-like air pump, and is configured to perform suction and discharge by operating the syringe 102. Note that switching of the spotting nozzle 91a and the suction flow path of the suction means 2 is performed by switching a solenoid valve (not shown) provided in the syringe means 19.
[0038]
Then, the spotting means 17 performs suction by lowering the piston of the syringe 102 while the tip of the nozzle tip 25 is immersed in the diluent or plasma in the diluent cup 16e or the cup 1e of the plasma filtration unit 9. Rotating to the spotting unit 13, a predetermined amount of spotting is performed on the chemical analysis slide 11.
[0039]
Next, the operation of this embodiment will be described.
[0040]
10 to 13 are flowcharts for explaining the operation of this embodiment. First, as shown in FIG. 1, before the analysis is performed, the chemical analysis slide 11 is set in the slide standby unit 12, the sample storage unit 16 which is a consumable is set, and then the analysis process is started. At this time, the reference liquid chip holding part 16a, the electrolyte specimen chip 16b, the reference liquid storage pipe 16c, the diluent chip holding part 16d, the blood collection tube holding part 16g, and the specimen chip holding part 16h of the sample storage part 16 are provided. A reference liquid chip 25a, an electrolyte specimen chip 25b, a reference liquid and a diluent chip 25d, a blood collection tube 7 having blood for analysis, and a specimen chip 25h are held, respectively. In this embodiment, the electrolyte specimen chip 25b and the reference liquid chip 25a are not used.
[0041]
First, in step S1, the biochemical analyzer is initialized, and in step S2, whole blood in the blood collection tube 7 is filtered by the blood filtration unit 9 and the suction means 2 to obtain a plasma component. FIG. 11 shows a flowchart of processing performed in the blood filtration unit 9 and the suction unit 2. First, in step S21, the liquid level detection sensor 2d is checked for contamination, and a reference plate is set at the height position of the cup 1e to set the gain of the liquid level detection sensor 2d. Next, in step S22, the spotting arm 88 is rotated to a position where the suction cup 2b of the suction means 2 faces the holder 1, and the spotting arm 88 is further lowered to bring the lid 1B and the suction cup 2b of the holder 1 together. Abut each other. In step S23, the syringe means 19 is driven to apply a negative pressure to the space formed between the lid 1B and the suction cup 2b. As a result, blood is filtered by the filter 3 and plasma is supplied to the cup 1e through the nozzle supply port 1f. At this time, the pressure of the syringe means 19 may be checked to detect a leak or blood hematoma.
[0042]
In the next step S24, the liquid level detection sensor 2d detects that a predetermined amount of plasma has been supplied to the cup 1e, and the drive of the syringe means 19 is stopped. At this time, instead of the liquid level detection sensor 2d, the driving of the syringe means 19 may be stopped after a certain suction time has elapsed. Next, in step S25, the release valve of the negative pressure supply unit 2c is released to finish the pressure reduction, and in step S26, the landing arm 88 is lifted to release the contact between the lid 1B and the suction cup 2b. Then, the spotting arm 88 is returned to the original position (position shown in FIG. 1), and the process is terminated.
[0043]
Returning to FIG. 10, in step S <b> 3, the transport unit 15 transports the slide 11 from the slide standby unit 12 to the spotting unit 13. In the spotting unit 13, the barcode provided on the slide 11 is read by the barcode reader 130, and the inspection item of the slide 11 is detected. If the read inspection item is a dilution request item, the process proceeds to A1 described later. . When the read inspection item is the measurement of the coloration degree, in the next step S4, the spotting arm 88 is moved to the sample storage unit 16 and the sample tip 25h is attached to the spotting nozzle 91a. In step S5, the liquid level of the specimen (plasma) supplied to the cup 1e is detected, and it is confirmed whether the liquid level and the necessary plasma are supplied to the cup 1e. In step S6, the landing arm 88 is lowered to suck the sample from the cup 1e into the sample chip 25h. A specimen is spotted on the spotting hole 11a. At this time, the clogging of the chip 25h may be detected by monitoring the pressure change and comparing it with a predetermined value.
[0044]
In step S8, the slide 11 on which the sample is spotted is inserted into the incubator 14. The incubator 14 has an internal temperature set to 37 ± 0.2 ° C. for measuring the coloration degree. At this time, it may be detected whether or not the slide 11 is securely inserted into the incubator 14. When processing is performed continuously, in step S13, another slide 11 is conveyed to the spotting unit 13, and the barcode is read to perform the processing from step S6 to step S8. At this time, when the read inspection item is a dilution request item, the process proceeds to A2 to be described later.
[0045]
When the slide 11 is inserted into the incubator 14, the storage portion 55 of the incubator 14 is rotated, and the inserted slide 11 is sequentially moved to a position facing the photometric head 27. In the next step S9, the reflection optical density of the slide 11 is measured by the photometric head 27. After completion of the measurement, the chemical analysis slide 11 after the measurement is pushed to the center side of the incubator 14 by the conveying means 15 for inserting the slide 11 into the incubator 14 and discarded. In step S11, the measurement result is output. In step S12, the used sample tip 25h is removed from the spotting nozzle 91a by the tip extraction unit 20, dropped and discarded, and the process is terminated.
[0046]
In outputting the measurement result, an identifiable mark (for example, P) may be added to the data in the output table in order to distinguish the filtered blood data from the unfiltered blood data. Good.
[0047]
Next, the case where the inspection item is a dilution request item will be described with reference to the flowcharts shown in FIGS. This dilution request item is performed, for example, when the blood concentration is too high to perform an accurate test. First, in step S31, as in step S4 of FIG. 10, the spotting arm 88 is moved to the sample storage unit 16 and the sample tip 25h is attached to the spotting nozzle 91a. In step S32, the liquid level of the specimen (plasma) supplied to the cup 1e is detected, and it is confirmed whether the liquid level and the necessary plasma are supplied to the cup 1e. In A2 in FIG. 10, the processing from step S33 is performed. In step S33, the spotting arm 88 is lowered and the sample is aspirated from the cup 1e to the sample chip 25h. At this time, the clogging of the chip 25h may be detected by monitoring the pressure change and comparing it with a predetermined value.
[0048]
In the next step S34, the aspirated sample is dispensed from the sample chip 25h into the mixing cup 16f. After dispensing the sample, in step S35, the used sample tip 25h is removed from the spotting nozzle 91a by the tip extraction unit 20 and dropped and discarded downward. Next, in step S36, the spotting arm 88 is moved to the sample storage unit 16, and the diluent tip 25d is attached to the spotting nozzle 91a. In step S37, the liquid level of the diluent supplied to the diluent cup 16e is detected, and it is confirmed whether the liquid surface position and the necessary diluent are supplied to the diluent cup 16e. In step S38, the landing arm 88 is lowered and the diluent is sucked from the diluent cup 16e into the diluent tip 25d. At this time, the clogging of the chip 25d may be detected by monitoring the pressure change and comparing it with a predetermined value.
[0049]
In the next step S39, the sucked diluent is discharged from the diluent tip 25d to the mixing cup 16f. In step S40, the diluent tip 25d is inserted into the mixing cup 16f, and agitation is performed by repeating suction and discharge. After stirring, the specimen diluted in step S41 is sucked into the specimen chip 25h, the spotting arm 88 that sucked the specimen diluted in step S42 is moved to the spotting section 13, and the spotting hole of the slide 11 is moved. Drop the specimen on 11a. At this time, the clogging of the chip 25d may be detected by monitoring the pressure change and comparing it with a predetermined value. If processing is to be performed continuously, slide conveyance and barcode reading are performed in step S43, and processing in steps S41 and S42 is performed.
[0050]
In steps S45 to S49, photometry, slide discard, result output and chip discard are performed in the same manner as in steps S8 to S12 in the flowchart of FIG.
[0051]
As described above, in the present embodiment, plasma can be separated from blood simply by performing suction using the blood filtration unit 9, and plasma separation can be performed only by loading the blood collection tube 7 with the blood filtration unit 9. Since the analysis can be performed, plasma can be separated from the blood and analyzed in a short time compared to the case of using a centrifuge. For example, when a centrifuge is used, it takes about 10 minutes to separate plasma, but by using the blood filtration unit 9, the time for plasma separation is reduced to about 1 minute. Thus, it is possible to cope with urgent biochemical analysis of blood.
[0052]
Further, since the suction arm 2 for spotting plasma or the like is provided with the suction means 2 for sucking and filtering plasma by connecting to the blood filtration unit 9, it is necessary to provide a mechanism for driving the suction means 2 separately. Accordingly, the configuration of the apparatus can be simplified, and the apparatus can be configured at low cost.
[0053]
Note that the number of storage units 55 of the chemical analysis slide 11 of the incubator 14 in the above embodiment is arbitrary. Moreover, the blood filtration unit 9 may also be provided at an arbitrary position.
[Brief description of the drawings]
FIG. 1 is a schematic plan view of a main part mechanism of a biochemical analyzer according to an embodiment of the present invention.
FIG. 2 is a diagram showing the configuration of a plasma filtration unit
FIG. 3 is a diagram for explaining the state of blood filtration;
FIG. 4 is a cross-sectional front view of a conveying means portion.
FIG. 5 is a cross-sectional front view of the incubator part.
FIG. 6 is a diagram showing a configuration of a sample storage unit
FIG. 7 is a sectional front view of the spotting means portion.
8 is an enlarged view in the direction of arrow A in FIG.
FIG. 9 is a diagram showing the structure of a chemical analysis slide.
FIG. 10 is a flowchart showing a measurement process of a coloration degree.
FIG. 11 is a flowchart showing processing in the blood filtration unit.
FIG. 12 is a flowchart showing a process for performing a dilution operation (part 1);
FIG. 13 is a flowchart showing a process for performing a dilution operation (part 2).
[Explanation of symbols]
2 suction means
5 Blood filtration device
9 Blood filtration unit
10 Biochemical analyzer
11 Chemical analysis slide
13 point attachment
14 Incubator
15 Transport means
16 Sample compartment
17 Spotting means
25 Nozzle tip
88 point arm

Claims (2)

In a biochemical analyzer for obtaining a concentration of a predetermined biochemical substance in the sample solution using a chemical analysis element on which the sample solution is spotted,
A filter for filtering whole blood to obtain a filtrate as a sample liquid , and a blood filtration unit provided on the outlet side of the filtrate , and having a filtrate receiving tank for receiving the filtrate;
Wearing means point is spotted filtrate within said filtrate receiving tank to the chemical analysis element, and wherein the action of negative pressure to the blood filtration unit from the outlet of the filtrate, the outlet side of the filtrate A biochemical analysis apparatus comprising: a spotting arm having suction means detachably provided.   The receiving part which receives the filtrate from the said filtrate receiving tank, The dilution unit which mixes dilution liquid in this receiving part and dilutes the filtrate in the said receiving part was further provided, The dilution unit of Claim 1 characterized by the above-mentioned. Biochemical analyzer.

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