DE3921393A1 - Appts. for automatic photometric analysis of e.g. blood - contains liq. specimen and reagent transfer devices and cuvette transport mechanism - Google Patents

Abstract

An arrangement for automatic photomeric liq. analysis contains at least one measurement station (16) with at least one optical transmitter-receiver and a specimen cuvette transport mechanism. A specimen store (10) has holders for specimen containers identified by an identifying device (44). Liq. is transferred (18) from a specimen container in the specimen store to one or more cuvettes passed to a filling station. Reagent is transferred (20) into the cuvettes before they reach the measurement station. A control and evaluation arrangement (46) is connected to the transfer and identification devices. USE/ADVANTAGE - For trouble-free, rapid, automatic testing, e.g. of blood in hospitals.

Description

The invention relates to a device for automatic gene photometric analysis of liquid samples according to the preamble of claim 1.

When examining liquid samples, for example wise blood tests in laboratories and hospitals, it happens depending on the circumstances, various tests at the Currency of an optimal execution of the tests on a large number of liquid samples in a short time few personnel to perform, the samples not may be exchanged.

When examining blood, for example Blood after centrifugation is drawn to the blood plasma separate from the other blood components. The blood sample must be labeled and it must be marked on it attention is paid that the now carried out  Tests the blood sample and thus the patient can be clearly assigned. From the The blood plasma must be removed from the centrifuge tube be transferred to measuring cuvettes. It is about make sure that the centrifuged solid loading components and do not mix the blood plasma again. For the implementation of the various tests are on finally certain reagents of the investigated Liquid is added, whereupon the measuring cuvettes after a certain reaction time in the measuring station be introduced. The reaction of the blood plasma with different reagents can now be measured optically and be evaluated. When carrying out the Untersu in the conventional way, there is always Danger that the quality of the measurement results due to sent handling of the samples and by the procrastination of sample residues or chemical residues from one Sample in the other will be affected. Also best hen many ways that the clear zu order the measurement results for a specific sample is lost during the execution of the tests.

The invention has for its object a Vorrich tion of the type mentioned at the beginning, which can be found under Avoiding the disadvantages described above flawless, rapid and automatic execution of Tests allowed.

This task is carried out by the solved 1 specified characteristics.

In the arrangement according to the invention, it is only required the sample container, i.e. for example the centrifuge tubes into the receptacles of the samples able to bring. All other processes run themselves active from. Because by means of the identification device  each sample container is identified and evaluated in the and control device is registered and since the Rei sequence of the cuvettes in the cuvette template and thus is also fixed when passing through the measuring station a clear assignment of the measurement results to a certain sample guaranteed. The use of two Transfer devices for transferring samples liquid from a sample container into the cuvettes on the one hand and for transferring reagents into the Measuring cells on the other hand ensure that not Sample liquid carried into the reagent container is and these ver very expensive reagents rages. Another advantage of the Lö according to the invention solution can be seen in the fact that the sample container after the insertion into the sample template no longer moves will. This reduces the risk that for example in blood tests after the Centrifuge separated components of the blood all mix slowly again and investigate blood plasma is clouded. Another advantage can be seen in the fact that because of the automation of the The possibility of infection in the laboratory personnel by the samples to be examined considerably is reduced.

After carrying out the measurements, the Measuring cells placed in the waste or automatically be used for further use.

The arrangement is preferably such that the Sample template at least one sample holder with a A plurality of openings arranged in a row for Recording from the sample tube or the like and a by means of a sliding guide between two End positions displaceable carrier pad includes on which the sample carrier is releasably attachable, and that the  Identification device a touch device summarizes the along the sliding path of the support pad is arranged in such a way that it is attached to the sample tube brought marks marks when the sample carrier from one end position to the other End position is pushed. The sample carrier is at for example, with sample containers where the Samples are taken. Then he becomes Brought measuring device, placed on the support pad sets and pushed past the feeler, whereby all sample tubes are scanned and identified the. Provided that the sample tubes until the end of the Measurements are then no longer interchanged, is therefore a clear assignment of measurement results to the liquid samples and thus e.g. to be agreed patients guaranteed. The sample tubes then no longer need to be moved.

Preferably, several are parallel to each other slidable support pads arranged side by side. This not only has the advantage of reducing the stock looking for sample tubes and thus also the intervals to be able to enlarge, in which the operating personnel must act, but there is also the possibility speed, a sample holder with a hurry to be examined To insert and pull samples on a support pull without changing the order of the previous already inserted and identified sample tubes needs to be changed.

Identification can be done easily by performing the sample tube when filling with the liquid to be examined with one which he required data contained code track, for example  be provided with a barcode that can be read using an opti the reading device can be scanned.

The transmission devices each include a pa parallel and perpendicular to the transport plane of the cuvettes adjustable cuvette, each with one over the Evaluation and control device controllable pump is linked to dosed amounts of substances to be able to take and deliver. The pipette can can be heated by means of a regulated heating device, around the substances to be examined or, for example also the reagents cooled until they are used bring to the optimal temperature for the measurement can.

A sensor for measurement is preferably on the pipette the level in the sample tube and / or the Reagent containers arranged to ensure that always the necessary to carry out the measurement amount of the substance to be transferred is present.

To carry off sample residues into another Sample or reagent residues into another Avoiding reagent containers is every transfer a washing station for cleaning the Assigned pipette.

The cuvette template preferably comprises two transports trains whose feed devices are independent of one another are drivable. This makes it possible to for example different cuvettes in the Save cuvette template, depending on which to go through leading measurement program can be used. The Transport lanes are each to accommodate one A plurality of cuvette bars are formed, one  Plurality of rows next to each other and at a distance comprise mutually arranged measuring cells and in the transport path transverse to its longitudinal direction are movable. The feed of the measuring cuvettes can done by a drivable slide that is on intended for contact with the last cell bar Contact surface pressure switch carries that when it occurs a certain feed resistance can be actuated and control the feed drive.

As different reagents for the different tests are needed, the Vorrich invention device preferably a reagent station for recording a plurality of reagent containers, these Reagent station one with a cooling device ver bound base and one that can be placed on top of it Containers carrier, and wherein the reagent containers with the container carrier with the base in touch stand. When the device started up the container carrier with the Reagent containers from a cooler, for example removed the cabinet and put it on the base, the cooling of the base ensures that the to Part of sensitive reagents not by heating spoil prematurely. After completion of the measuring processes the reagents can be quickly and easily removed in the refrigerator again be set. A good contact between the chilled This guarantees the base and the reagent containers makes the base a metallic heat sink with conical recesses to accommodate the conical ge molded reagent container.

Further features and advantages of the invention result from the following description, which in  Connection with the accompanying figures the invention explained using an exemplary embodiment. It demonstrate:

Fig. 1 is a schematic plan view of the inventive device,

Fig. 2 shows a schematic partial section along line II-II in Fig. 1,

Fig. 3 is an enlarged plan view of a portion of the transport path of the Küvettenvorlage,

Fig. 4 is a schematic sectional view of a used on the feed device for the cuvettes pressure switch,

Fig. 5 is a schematic section, the pipette containing the axis, by a device of the invention used in the pipette

Fig. 6 is a schematic, partially ge sectioned representation of part of the sample and

Fig. 7 shows a schematic section through the reagent station along line VII-VII in FIG. 1.

The apparatus shown in FIG. 1 for automatic photometric Anlyse of liquid samples comprising a sample template 10, a Küvettenvorlage 12, a conveyor 14 for conveying cuvettes to a measuring station 16, a first transfer device 18 for transferring sample fluid from sample containers in cuvettes and a second transfer device 20 for transferring reagents from a reagent station 22 into the cuvettes before they enter the measuring station 16 .

The sample template comprises a plurality of sliding guides 24 arranged parallel to one another, which can be formed in the manner of telescopic roller rails, for example, as are used as sliding guides in drawers. With the part 28 of the sliding guide 24 which is displaceably guided in a fixed rail 26 ( FIG. 6), a carrier support 30 is connected to which a sample carrier 32 can be placed. In this case, pins 34 connected to the carrier pad 30 engage in corresponding recesses 36 in the bottom of the sample carrier 32 , so that the latter assumes a defined position on the carrier pad 30 and has a secure hold. The sample carrier 32 consists of an elongated cuboid block with bores 38 arranged in a row, into which sample tubes 40 can be inserted. The sample carrier 32 as a whole can be lifted from the carrier support 30 together with the tubes 40 or placed thereon.

Each sample tube 40 carries a sticker 42 which is attached when the sample is taken and which bears a barcode which can contain information about the type of sample, the patient from whom the sample was taken and the type of measurements to be carried out.

Before the sample carrier 32 is placed on the support pad 30 , the part 28 of the sliding guide 24 is continuously pulled out of the fixed guide rail 26 . After the sample carrier 32 has been placed on the carrier support 30 , the sample tubes 40 are passed one after the other at the insertion of the sample carrier 32 past a reading head 44 which scans the barcode on the sticker 42 by means of suitable optics and thus identifies the sample tubes 40 . The scanned information is stored in an evaluation and control device, generally designated 46 . The depth of field of the optics is chosen so that the reading head 44 can detect the information on all sample tubes 40 in the adjacent sample carriers 32 when the sample tubes 40 cross the optical axis 48 of the reading head 44 .

The cuvette template 12 comprises two transport tracks 50 for receiving cuvette bars 52 ( FIG. 3), each of which has a plurality of cuvettes 56 lying next to one another and separated by gaps 54 . The cuvette latches 52 are formed in one piece. The side walls of the intermediate spaces 54 protrude somewhat beyond the measuring surfaces of the cuvettes 56 , so that the measuring surfaces of the cuvettes cannot be scratched when the cuvette latches meet or are transported into the measuring station.

The cuvette bars 52 are parallel to each other on the respective transport path 50 and can be advanced by a slide 58 in the direction of the conveyor device 14 . The slide 58 ( FIG. 2) is slidably guided on guide rods 60 running parallel to the transport tracks 50 . It carries on its underside a motor 62 , the output shaft of which is connected to a pinion 64 which meshes with a rack 66 running parallel to the guide rods 60 . The slide 58 is in contact with the last cuvette latch of the cuvette supply via two pressure switches 68 ( FIGS. 3 and 4). The pressure switch consists, for example, of a base plate 70 with a first contact element 72 and a cup-shaped part 74 made of an elastic material which carries a second contact element 76 . If a certain transport resistance is exceeded when the cuvette bar 52 is advanced, the elastic part 74 is compressed so that the contact elements 72 and 76 touch. The circuit is chosen so that when the contact motor 72 and 76 meet, the drive motor 62 for the slide 58 is switched off.

The transport tracks 50 are covered in a manner not shown in order to avoid contamination of the cuvettes. Near the mouths of the transport tracks 50 in the conveyor device 14 , the transport tracks 50 are covered with a cover 78 which has openings 80 which are aligned with the cuvettes 56 below, so that the cuvettes 56 can be filled through the openings 80 .

The transport paths 50 open out perpendicularly into a guide rail 82 of the conveyor 14, the sentlichen in we U-shaped, with 50 of a U-leg is missing in the area of junction of the transport paths, to around the insertion of a respective Küvettenriegels 52 in the guide rail 82 made possible, the cuvette latch 52 comes to rest on the other U-leg 84 serving as a stop. The width of the guide rail is chosen so that it corresponds exactly to the width of a cell bar. The U-legs 84 of the guide rail 82 can be heated in order to heat the cuvettes or their contents to a temperature required for the respective measurement. As can be seen from Fig. 3, the cuvette volume itself can be changed while maintaining the outer dimensions of the cuvette bar by increasing or reducing the spaces 54 . By providing two and possibly several transport tracks 50 , cell bars with different cell volumes can be kept ready.

The cuvette latch 52 is pushed forward in the guide rail 82 by means of a transport chain 86 , the chain links 88 of which carry pins 90 at intervals spaced to the length of the cuvette latch 52 , which protrude through a longitudinal slot in the bottom of the guide rail 82 ( FIG. 2) and advance the cuvette latch 52 in the guide rail 82 in the direction of the measuring station 16 . The transport chain 86 runs over two sprockets 92 , 94 , the latter being driven by a motor 88 via an intermediate gear 96 . This is a stepper motor that can be controlled by the evaluation and control device 46 .

The measuring station 16 conventionally comprises one or more optical measuring devices in order to be able to examine the samples in the cuvettes 56 . It can also be arranged in order to increase the throughput and to carry out the measurements more quickly two or more derar term measuring stations in the conveying direction.

At the end of the guide rail 82 there is a slide 100 , via which the processed cuvettes fall into a waste container. Instead of the slide 100 , a switch can also be provided, which allows the cuvettes to be used for a further purpose.

The transmission stations 18 and 20 are of the same design, so that it is sufficient to describe the transmission station 18 in more detail. The transmission device 18 comprises a transport head 102 which can be moved with a first linear motor along a fixed, fixed rail 104 running parallel to the guide rail 82 . The transport head 102 in turn guides, by means of a second linear motor, a rail 106 which can be displaced perpendicularly to the fixed rail 104 and which carries a pipette holder 108 at its end facing the sample holder 10 ( FIG. 2). The pipette holder 8 is at the lower end of a rack 110 vertically adjustable rack 112 be fastened. This meshes with a pinion, not shown, which is driven by a motor 116 via a shaft 114 , which is located on the end of the rail 106 opposite the pipette carrier 108 . In this way, the cuvette carrier 108 can be adjusted in any desired position both in a plane running parallel to the guide rail 82 and perpendicularly to the latter.

The pipette carrier 108 holds a pipette 118 with a pipette tube 120 , which is connected at its upper end via a hose 122 to a pump (not shown) and is surrounded by a jacket 124 . The pipette tube 120 carries a heating winding 126 , the heating power of which is regulated via a heating control 128 , the actual temperature value being determined using a temperature sensor 130 .

At the pipette tip, a not shown Level sensor can be arranged when immersed the pipette responds in a liquid, whereby from the position of the pipette when the Level sensor the level in the respective Liquid container can be determined.

The reagent station 22 comprises a metallic base 132 which carries cooling fins 134 on at least one side. These protrude into a duct 136 which is connected at one end to the outlet of a fan 138 . In this way, the base 132 can be cooled. The base 132 is provided on its upper side with a plurality of recesses 140 which are intended to receive conical reagent containers 142 . The conical shape ensures good contact between the walls of the reagent container 142 and the base 132 and thus reliable cooling of the reagents. The reagent containers also hang in holes 144 of a plate-shaped container carrier 146 , which is supported by two downwardly bent legs 148 on contact surfaces 150 of the base 132 . With the aid of the container carrier 146 , the reagent containers 142 can be lifted off the base 132 with a handle and placed in a refrigerator, for example, if they are no longer required after the measurements have been completed.

The device described so far works as follows:
When the sample tube 40 is inserted into the sample template 10 , the information on the stickers 42 is read in the manner described above and is stored in the evaluation and control device. This controls the transfer of sample liquid by means of the pipette 118 of the transfer device 18 into the cuvettes 56 in the manner predetermined by the information. The same sample liquid can be filled into several cuvettes 56 of the same cuvette bar 52 or different cuvette bars 52 , depending on whether different measurements on the different cuvettes 56 of a cuvette bar 52 or similar measurements on all the cuvettes of a cuvette bar are to be carried out in the measuring station 16 . After one or more cuvette bars have been filled, they are advanced by means of the slide 58 until the first of them abuts the leg 84 of the guide rail 82 . Then the transport chain 86 is set in motion, which moves the cuvette latch 52 inserted into the guide rail 82 in the direction of the measuring station 16 . By means of the transfer station 20 , the required reagents are filled into the cuvettes 56 , which can be done if the cuvettes are still in the cuvette template or already in the guide rail 82 . The reagents are preferably transferred into the cuvettes if they are still in the cuvette template, so that there is sufficient time to obtain a homogeneous solution at the desired temperature before the cuvettes then enter the measuring station 16 . After the measurement has been carried out, the cuvette bars are put into the waste via the slide 100 .

In order to avoid a transfer between two different sample tubes 40 or different reagent containers 142 , each transfer device 18 and 20 is assigned a washing station 150 or 152 , only indicated schematically, in which the pipette 118 is cleaned after each transfer process.

Claims (15)

1. Device for automatic photometric analysis of liquid samples, in particular liquid speeds with at least one measuring station ( 16 ) comprising at least one optical transmission / reception arrangement ( 16 ) and a conveying device ( 14 ) for transporting the cuvettes ( 56 ) holding the liquid samples through the measuring station ( 16 ), characterized by a sample template ( 10 ) with a plurality of receptacles ( 36 ) for sample containers ( 40 ), an identification device ( 44 ) for identifying the sample containers ( 40 ), a cuvette template ( 12 ) with at least one transport path ( 50 ) for supplying cuvettes ( 56 ) to a filling station and for transferring the filled cuvettes ( 56 ) to the conveying device ( 14 ), at least one first transfer device ( 18 ) for transferring sample liquid from a sample container ( 40 ) in the sample template ( 10 ) in one or more cuvettes ( 56 ) in the filling station, at least one between eite transfer device ( 20 ) for transferring at least one reagent from a reagent container ( 142 ) into one or more cuvettes ( 56 ) before they enter the measuring station ( 16 ) and one connected to the identification device ( 44 ) and the measuring station ( 16 ), the transmission devices ( 18 , 20 ) controlling evaluation and control device ( 46 ). 2. Device according to claim 1, characterized in that the sample template ( 10 ) at least one sample carrier ( 32 ) with a plurality of rows arranged openings ( 38 ) for receiving sample tubes ( 40 ) or the like and one by means of a sliding guide ( 24 ) between two end positions movable carrier support ( 30 ) on which the sample holder ( 32 ) can be releasably placed, and that the identification device comprises a probe ( 44 ) which is arranged along the sliding path of the carrier support ( 30 ) such that it is on marks ( 42 ) arranged on the sample tube ( 40 ) when the sample carrier ( 32 ) is pushed from its one end position into its other end position. 3. Apparatus according to claim 2, characterized in that a plurality of mutually parallel carrier supports ( 30 ) are arranged side by side. 4. Apparatus according to claim 1 or 2, characterized in that the sample tubes ( 40 ) carry a code track which can be scanned by means of an optical reading device ( 44 ). 5. Device according to one of claims 1 to 4, characterized in that the first and the second transmission device ( 18 , 20 ) each include a pa rallel and perpendicular to the transport plane of the cuvettes ( 56 ) adjustable pipette ( 118 ), each with a pump which can be controlled via the evaluation and control device ( 46 ) is connected. 6. The device according to claim 5, characterized in that the pipette ( 118 ) can be heated by means of a regulated heating device ( 126 , 128 , 130 ). 7. Apparatus according to claim 5 or 6, characterized in that a sensor for measuring the level in the sample tube ( 40 ) and / or the reagent container ( 142 ) is arranged on the pipette ( 118 ). 8. Device according to one of claims 5 to 7, characterized in that each transmission device ( 18 , 20 ) is assigned a washing station ( 150 , 152 ) for cleaning the pipette ( 118 ). 9. Device according to one of claims 1 to 8, characterized by an upwardly open U-shaped guide rail ( 82 ) in which a plurality of cuvettes ( 56 ) comprising elongated cuvette bars ( 52 ) in contact with the U-legs ( 84 are displaceable) of the guide rail (82) and a circulating transport chain (86) having one strand parallel to the longitudinal direction of the guide rail (82) and the chain links carry (88) intended for contact at the Küvettenriegeln (52) driver (90) . 10. The device according to claim 9, characterized in that at least the U-legs ( 84 ) of the guide rail ( 82 ) are heated. 11. The device according to claim 10, characterized in that the cuvette template ( 12 ) comprises two transport tracks ( 50 ), the feed devices ( 58 ) can be driven independently. 12. The apparatus according to claim 11, characterized in that the transport tracks ( 50 ) are each formed to take on a plurality of cuvette bars ( 52 ), which comprise a plurality of row-shaped side by side and spaced apart measuring cuvettes ( 56 ) and are displaceable in the transport path ( 50 ) transversely to their longitudinal direction. 13. The apparatus of claim 11 or 12, characterized in that the feed device comprises a drivable slide ( 58 ), on its abutment against the last cuvette bar ( 52 ) be wearing contact surface pressure switch ( 68 ) which occurs when a certain occurs Feed resistance can be actuated and control the feed drive ( 62 ). 14. Device according to one of claims 1 to 13, characterized in that a reagent station ( 22 ) for receiving a plurality of reagent containers ( 142 ) is provided, comprising a base ( 132 ) connected to a cooling device ( 136 , 138 ) and a container support ( 146 ) which can be placed on this, the reagent containers ( 142 ) being in contact with the base ( 132 ) when the container support ( 146 ) is attached. 15. The apparatus according to claim 14, characterized in that the base ( 132 ) comprises a metallic cooling body with conical recesses ( 140 ) for receiving the conically shaped reagent container ( 142 ).