DE2265560C2 - Device for preparing a number of physiological fluids for analysis - Google Patents

Description

characterized in that the means for adding reagents are as follows Features include:

20th

a) there are several reagent containers for each different reagents provided.

b) the reagent containers are pressurized with an inert gas at constant pressure,

c) each of the reagent containers is an associated with an associated Abgabeleityng, as Shut-off valve acting reagent valve (388) downstream,

d) each group of reagent valves is followed by a metering valve (436) which is used for ίο one de; intended dosage corresponding duration be,? activated -st, and

e) in each case a group of metering valves (436) is connected to a dispensing head via lines (373) ml * (27, 28) connected for filling the reagents into the reaction vessels (33).

2. Device according to claim i, characterized in that each of the metering valves (436) one Group with an associated delivery passage (376; 380) in the delivery head (27, 28) each via one separate line (375) is connected.

The invention relates to a device for processing a number of physiological fluids for Analysis according to the preamble of claim 1, as known from DE-AS 11 68 674. w

In this known device, sample containers with a first conveying direction become one Transfer arm conveyed, which successive samples on a second conveyor transmits, in which a device for adding at least one reagent is provided.

This device has a pumping device for the particularly precise supply of reagents has its own metering device with a specially designed pump. f> o

The known device eliminates some of those sources of error that occur when a Laboratory technician adds the reagents to the individual reaction vessels by hand, if one of the for this purpose required, considerable amount of work and time t » want to forego completely.

For more complicated investigations, however, it is not enough to just add a single reagent. Further the known device is basically controllable by means of a logic switching device, but then a separate metering pump would have to be provided for each reagent, since this is done by means of a Tax impulse would only be adjustable in their volume promotion.

Based on this prior art, the invention is based on the object on de? basis this known device to create a versatile analysis device that is responsible for the control by a logic switching device is particularly suitable

This object is achieved by the features a) to e) of claim 1.

There are several reagent containers, each of which acts as a shut-off valve Reagent valve are connected.

A number of such reagent valves are each followed by a metering valve, which is connected to the Dispensing head for filling the reagents into the reaction vessels is in connection.

It is for the metered supply of fresh reagent required, first the reagent valve with an opening pulse and then the downstream dosing valve to be controlled with an opening impulse of a certain duration. To promote the reagent through To achieve these valves in the dispensing head is - as already known from FR-PS 20 63 695 - each of the Reagent container acted upon with an inert gas which has a certain pressure. If this Pressure is kept essentially constant, then the opening time of the respective metering valve is directly proportional to the amount of reagent delivered.

It is possible with the device according to the invention, any number of reagents by means of one single metering valve to the extent that these reagents are compatible with each other, so that one gets by with a minimum number of metering valves.

The reagent and dispensing valves can each be controlled by means of a simple control pulse, where only the duration or interval length is decisive for the control pulses, but not the Intensity. A regulation, i.e. a feedback between the logic circuit and the controlled valve, is not required because of the high reliability of such known valves.

Thus, even the most complicated analyzes can be carried out with the device according to the invention, to which a large number of precisely dosed reagents is required, since it is logical Circuit is not a problem. carry out an arbitrarily complicated program, and on the other hand the The device according to the invention can be designed for practically any number of reagents whose Feeding and dosing are each carried out with the highest degree of accuracy.

It is already known (DE-OS 15 98 622). multiple reagents in a single reagent container admit, but there is no indication in this document that there are several such facilities can be designed as the same devices and interconnected in groups.

It is also known (US-PS 35 36 450). an inert gas to be used in conjunction with an analysis device, but this inert gas only has the Purpose, in cooperation with a buffer tank and a water tank to ensure that in Reagent containers do not create negative pressure when a reagent is pumped through a dip tube

is sucked off. This publication is also not a Note that, for example, the inert gas pressure, which is kept constant, can be controlled by a time-controlled valve would be able to take over the entire and in particular the exact = dosing of the reagents.

The subject matter of the invention is explained in more detail with reference to the schematic drawing. In this shows

F i g. 1 is a view of a combined dispensing and mixing head in vertical section, ι ο

F i g. 2 shows a plan view of a selection device for reagents with associated dispensing valves,

F i g. 3 is a view in section along the line 14-14 in FIG.

F i g. Figure 4 is a sectional view taken along line 15-15 in Fig. 2,

F i g. 5 shows another embodiment of the combined dispensing and mixing head in vertical section,

6 is a partially sectioned plan view to another embodiment of the reagent selection device with the associated valves,

Fig.? a partially shown in section «: side view the valve arrangement in the device according to FIG. 6, and

F i g. 8 is a sectional view taken along line 25-25 in FIG. 7th

The analysis device shown in the drawing is used for the serial examination of serum samples, the individual patients are taken in a conventional manner. The term "serum" denotes in jo following each physiological fluid the electronic used to control the device Control arrangement is shown and described in DE-PS 22 44 260.

The analyzer contains a holding and j5 Transport device 18 (Fig. 1) for a number of containers 33 for sample batches (reaction vessels 33) and dispensing means for optionally introducing at least one reagent into the containers 33 their transport by means of the holding and transport device, for the production of trial batches. First the holding and transport device 18 for the sample approaches is a removal device for Removing a certain amount of the sample approaches contained in the sample containers 33 are arranged.

The dispensing device has at least one dispensing head 27, 28 for introducing at least one Reagent in the individual containers 33 for sample approaches as well as a selection device 384 connected to it for "> n Selecting and supplying the reagent to be dispensed from a number of different reagents. the Selector 384 includes a number of each with a pressurized container for Reagent-connected valve assemblies 393, 395 v> (Fig. 3).

Furthermore, the device preferably contains mixing devices 356 for the optional mixing of the Contents of the container 33 for sample batches.

The mixing devices have a motor 368 and a drive connected to the motor Mixer part 361, with the mixing device drive devices 359 for its reciprocating Movement are connected, by means of which the mixer part while dipping into or pulling out b5 from the contents of the container for sample batches can be introduced into them or executed therefrom, with a Mixing of the contents can be brought about by the rotating mixer part

The mixing device can also have a mixer part 716 through which the one passage 718 extends, one on the compressed gas source connected to the passage and drive means 706 for moving the mixer part into individual containers 33 for sample approaches and out of these with immersion of the mixer part its passage into the contents of the same, whereby by a gas flow through the contents a thorough mixing of the same can be brought about through it (Fig. 5).

In a preferred embodiment of the invention, the reagent dispensing devices at least one delivery head 27,28, with at least a passage 376, 380 for reagents therein; an array 384 of valves (FIG. 2) for the predeterminable Selecting reagents to be dispensed and an arrangement of metering valves 436 for the predeterminable Controlling the amount of a reagent to be dispensed in each case during a dispensing process.

The sample glasses seated in the transport disk 18 and transport device 18 pass under delivery heads (eg 27, 28) after leaving a transfer station. The first rounds can be made by turning empty sample jars into the upper guide position for loading with serum samples. A first dispensing head is only used to dispense additives, that is to say, unlike the otherwise identical dispensing heads 27 and 28, it does not have devices for mixing the reagents dispensed with the serum sample. The mixing devices assigned to the dispensing heads 27 and 28 serve to mix reagents supplied via the relevant heads with the serum samples and to distribute them uniformly therein. The even distribution of the reagents serves to avoid local overconcentrations of the same in the serum sample, which could lead to incorrect results in the subsequent analysis of the sample.

An example of a combined mixing and dispensing head 27 or 28 is shown in FIG. 1 shown. The head is held in the upper part of a lower housing 12 by means of screws 357 and is essentially exposed a lower delivery device 354 and a mixing device 356 arranged above it. While the dispensing device 354 is arranged stationary, the mixing device 356 is by means of one at the top Attached end to it and at the lower end to the piston of a pneumatic cylinder (not shown) Push rod 359 can be moved up and down. When the cylinder moves up and down, a RUhrstab 361 optionally in the sample preparation in one submerged the sample tube below. The stir bar 361 extends from the mixing unit 356 through a bore 362 in the stationary dispenser 354 and is at the top via a coupling 365 connected to the shaft 366 of an agitator motor 368. The stir bar 361 is made from a bar 371 stainless steel and a piece of pipe 373 pushed onto this made of a chemically neutral and resistant material such as tetrafluoroethylene educated. The lower end 374 of the pipe section 373 is against the penetration of the examination liquid closed.

In operation, reagents are selected by means of an arrangement described below via separate lines 379 three in the dispensing entry

Direction 354 formed passages 376 supplied. The passages 376 lead to above the standing one Sample glass 33 opening openings 380 through which the reagents are dispensed. Afterward the mixing device 3S6 is moved downwards by means of the pneumatic cylinder (not shown), whereupon the agitator motor 368 is switched on via the logic control arrangement. The fast Rotation of the in the sample glass 33 with the combination of the serum sample and the contained therein The stirring rod 361 lowered via the dispensing device 354 causes a rapid and uniform mixing of the reagents with the sample.

In response to a signal emitted by the logic control arrangement, the rod 359 is again from Pneumatic cylinder extended so that the stirring rod 361 comes out of the sample glass (reaction vessel) 33 lifts, and the agitator groove 36S becomes äugcsciiäiici. The high speed of the stirring rod of, for example, about 6000 rpm, in conjunction with the Surface properties of the rod 361 that when the rod is lifted out of the test tube (reaction vessel) adhering parts of the sample are thrown off, so that a mutual Contamination of consecutive samples is not possible. The transport disk 18 is now turned further to bring an empty tasting glass to a transfer station, which is the one formed and mixed sample preparation containing sample glass 33 to the next dispensing head 28 or arrives at an analysis extraction station.

Another embodiment of the dispensing and mixing head, in which a different mixing technique is used, is shown in FIG. 5 shown. It is also essentially composed of a fixed lower tail 7ΩΊ iinsl

mixer part 704 which can be moved up and down by means of a pneumatic cylinder 706. A pressurized gas for the actuation of the cylinder 706 is from a pressurized gas source via a manifold block 708 and a passage 710 formed therein is fed to the inlet 712 of the cylinder 706. The passage 710 in the Manifold block 708 is, for example, a pipe drawn into it, which protrudes from it at the bottom and is attached to it a hose 714 brought in from a valve of the pressurized gas source is connected. For poetry A connection part 717 made of rubber is used to connect the pipe section 710 to the hose 714. These The two-part design allows for easy removal of the distributor block 708 from the top of the lower case 12.

When pressurized gas is supplied to the inlet 712 of the cylinder, the mixer part 704 descends, whereby a Mixing tube 716 essentially to the bottom of one below the assembly Trial glass is introduced into this. The mixing tube 716 is made up of a tube 718 made of stainless steel Steel and a piece of pipe 720 made of flexible, chemically neutral material, e.g. B. Tetrafluoroethylene formed. Within the mixing part 704, the two pipe parts 718 and 720 are through by means of a Threaded secured rubber nipple 722 held together.

The tube 718 protrudes only a short distance beyond the rubber nipple 722, while the flexible Pipe section 720 led out of the mixer part 704 at the top and on one of the rear wall 726 of the same seated flow control valve 724 is connected.

After certain reagents have been added via discharge tubes 728 to the sample tube 33 sample contained is the inlet 712 of the cylinder; a pressurized gas supplied. The compressed gas pushes one Arrangement 740 (Fig. 6) of a piston and a piston rod in the cylinder 706 downwards. The top end the piston rod 730 is at the bottom of the

ίο mixer part 704 attached. This now becomes the Mixer part 704 guided along a vertical rod 732 into the position shown in FIG. 5 drawn in solid lines Lowered position. The mixing tube 716 emerges from the lower dispensing part 702 and into the

, 5 sample glass 33. At the same time it is an inert gas via the control valve 724. for example nitrogen supplied. This emerges at the lower end of the tube 716 in the form of bubbles, which then rise in the liquid currently contained in the sample 33 and emerge from its surface. The intensity of blowing through the mixture via the valve 724 results in thorough mixing of the combination of serum and reagents present in the sample tube 33 at this point in time.

After a predetermined mixing time in accordance with the logic control arrangement, this will be the Cylinder 706 closed with valve feeding compressed gas, whereupon a spring (not shown) in the cylinder converts the mixer part 704 into the one shown in dashed lines in FIG upper position returns. Reaching the upper end position of the mixer part 704 becomes the logical one Control arrangement via a magnetic (not shown) seated approximately at the lower end of a pin 734 Scanning device reported. The pin 734 extends through the dispensing part 702 and is in a threaded bore 736 screwed into mixer part 704. Together with the scanning device for the vertical position of the mixer part mainly serves the purpose of further turning of the transport disk 16 prevent as long as the mixer part 704 is in its lower position.

The arrangement for selecting the reagents required in each case and for controlling each

The quantities to be dispensed from this are shown in FIG. 2 to 4 shown. This has a valve block 384 with a main valve housing 386 on. which the latter is composed of six individual valve housings 388, for example is. Each valve housing 388 has an actuating solenoid 390 and five individual ones associated therewith double-sided reagent valves. The respective actuation magnetic coils 390 each have an actuating shaft 394, which penetrates the valve housing 388 and is attached to one by means of spring washers 398 Actuating rail 396 is attached

Via the operating rail 396, the solenoid 390 controls the upper and lower ends of five, respectively valve stems 404 assigned to valves 392. At the upper end of each valve 392 there is one Return spring 400 inserted between two stages 402. The valve stems 404 extend through the Valve housing 388 through and are at the lower end by means of spring washers 406 on the actuating rail 396 attached The individual valves point at each end

a central bore 408 or 410. each of which ends in a cross hole 412 or 414 The cross holes 412 and 414 are separated from and from each other by several O-rings 416 arranged in pairs

respective valve housing 388 penetrating channels 418 and 420 separately.

The upper ends 393 of the valves 392 are each assigned to a different examination or other examinations than the lower ends 395 Both ends 393 and 395 of the various valves are connected to the central bores 408 and 408 respectively. 4l?, For example via hoses made of tetrafluoroethylene, each connected to storage bottles containing various reagents in the lower housing 12. The ones in the The reagents contained in the bottles are made using compressed nitrogen gas, which is chemically neutral and does not alter it caused, kept under constant pressure.

In operation, the one on the bottles is used the required reagents connected to valves 392 solenoid coil 390 energized to the Extend actuating shaft 394 and thus the relevant actuating rail 396 from the valve housing 386 move away. The actuating rail 396 takes that of the relevant magnet coil 390 associated valve stems 404 of the five valves with. The movement of the valve stems 404 causes the two transverse bores 412 and 414 of the same in flow connection with the two passages 418 and 420 of the valve housing. Only one solenoid 390 is used at a time for any given exam actuated with the associated valves 392 Valve housing each of the in the via hoses ap the ends 393 and 395 of the actuated valves connected bottles containing ten reagents are available. In the valve housing 386 Continuously penetrating passages 418 and 420, the reagents can each between the O-ring pairs 416 surrounding passages flow around the stems 404 of the inoperative valves.

As for any kind of examinations only the lower or the upper ends of the valves supplied reagents are required, the flow connection of the two ends 393 and 395 be optionally producible. For this purpose, a magnetic coil 424 is provided, which moves an actuating rail 426 depending on the end of the valves 392 assigned to a specific examination Selector slide 428 for the upper or lower end of the valves 392 has two steps 430 on the upper part, between which a return spring 432 is inserted and is attached to the actuating rail 426 at the lower end, that is to say on the opposite side of the valve housing 386

As long as the dial magnet 424 is not excited a flow connection for the lower ends of the valves 392 (Figure 4). If the magnet 424 is excited so its actuating shaft 425 is extended, thereby moving the lower ends of the slides 428 holding actuator rail 426 away from the valve housing. This creates the flow path for the lower Ends 395 of the valves 392 are interrupted and one such from the upper ends 393 is assigned to them Outlet 434 established

The selected reagents flow through the respective upper or lower passages to the inlet side of extremely fast acting and accurate working metering valves 436. The metering valves 436 are connected to the outlet side via individual hoses 379 connected to the dispensing heads 27, 28. Two such valves are connected to one dispensing head 27.

and three valves with the other dispensing head 28.

The reagents required for an examination are immediately available when a series of tests is initiated the inlet side of the metering valves 436 described in the nen way fed. As soon as a serum sample is obtained containing sample glass is located under one of the dispensing heads, the metering valves 436 are optionally over actuates the logic control arrangement. The first dispensing head, which is not provided with a mixing device is used for the delivery of highly sensitive reagents with respect to contamination, such as are e.g. B. at Tests for cholesterol or glucose used are used. Such reagents contain the Risk of mutual contamination through which the Sample approaches would be unusable. You will therefore not supplied via the valve arrangement 384, but rather the same as the dispensing head via the metering valves 436 (not shown) further metering valves fed directly from the pressure-milled bottles 2US.

The main reagents are dispensed at the correct point in time by means of the dispensing heads 27 and 28 fed. The logic control arrangement operates the relevant metering valves 436 via one for each Delivery of a ^ certain amount of a certain

2; Reagent to the sample tube provided Period of time. After the dispensing has ended, the respective mixer part is lowered to allow the serum to be mixed with the to mix the added reagents. After mixing, the mixer part rises again and that The sample glass is rotated further to the next dispensing head 28 or, depending on the current position of the sample glass, to the removal station. After completing a series of examinations, the passages 418 and 420 of the valve housing 386 with a valve 437 is fed to an inlet 439 in the valve housing 386 Flushed with water.

Before the start of an examination, the valve arrangement 384 can be configured with those for the examination in question to be used reagents are flushed through.

A sample tube that does not contain a serum sample can be used for this purpose and which is sent to the individual Dispensing stations is rotated to collect the test reagents. The valve assembly 384 and reagents flowing through the metering valves 436 remove water present in it or from reagents left in previous studies.

Another embodiment of the valve arrangement for the selection of reagents is shown in FIG. 6 to 8 shown. That in Fig. The main part 738 of the valve arrangement shown in FIGS. 6 and 7 is composed of a multiplicity of individual valves 740 together, which are firmly connected to one another to form the overall arrangement 738. In the illustrated Example is the overall arrangement 738 in two blocks 742 and 744 broken down by individual valves each The block contains several rows of five individual 740 valves each. Any number can be used such rows exist. In the example shown, the right block 744 has eight rows 746 bis 753 and the other block seven rows 754 to 760. The

Valves in the first row 754 of the left block 742

serve as dosing valves for the supply to the dispensing and mixers of the heads 27 and 28.

The operation of the valve assembly 738 is on

it is best understood from Fig.8. Inside is one of the Individual valves 740 shown. It has a valve body 762 through which a bore 764 passes. In the The upper end of the bore 764 is an actuating magnet

766 screwed in with a thread 768. It contains a movable core 770 loaded by a spring 772, at the lower end of which an elastic disc 774 is seated. When the coil 775 of the magnet is excited, the movable core 770 with the disk 774 attached thereto is attracted by the compression of the spring 772. During the upward movement of the disk are 774 a into the bore ⁷ 64 of the valve body 762 opens intake port "76 free. Below the inlet port 776 is 777 connected by means of a threaded nipple 779, a line for the supply of a reagent by which the above pressure feed bottles The valve body is. penetrated by an inlet and outlet passage 778 and 780, respectively, opening into the bore 764. The inlet passage 778 extends in each case as an extension of the outlet passage 780 of the corresponding individual valve 740 in the row in front of it and is flow-connected to it the inlet passage 778 of the next following individual valve 740. The necessary sealing between the individual valves 740 is ensured by O-rings 782, 784. The arrangement of the inlet and outlet ports 778 and 780 is best shown in FIG.

The individual valves 740 are arranged in rows of five in each of the two blocks 742 and 744. For each one The five individual valves 740 of a row are used to test a serum sample actuated. In operation, the actuating magnets 766 of the five individual valves 740 are in one with the for the relevant investigation preprogrammed reagents fed rows as well as those of the dispensing valves in of the series 754 excited. From the series 746 to 753 and 755 to, each equipped with five individual valves 760 only those of one row are operated at a time. The inlets 776 of the actuated valves of a series Supplied reagents flow into the bores 764 the valve body and leave it via the drainage passages 780. From there they reach the The inlet passage of the next valve body, flow around the one closed by the elastic disc 774 therein Inlet 776 and leave the valve body concerned again via the drain passage 780. This flow continues until the reagents, provided the actuated row of valves in the left block reach the metering valves in row 754. If a row of valves in the right block 744 is actuated, then the appropriate reagents flow through the drainage passages 780 of the upper row 746 of Individual valves with passages 780 of the valves in series 754 corresponding to the drainage passages connecting lines 786 to 790 to the metering valves of the 754 series. The 754 series dosing valves have the same structure as the other individual valves, but with both passages 778 and 780 act as the inlet passage and the inlet 776 is used as the discharge passage at which the lines 379 leading to the dispensing and mixing devices 27, 28 are connected.

It can be seen that only those of the valve rows 746 to 753 and 755 to 760 which are actuated are assigned Reagents flow into the metering valves of the 754 series and exit via their drainage ports 776.

For example, if only three reagents are required for a particular test, the 754 series metering valves have all five reagents assigned to the valves of the operated series supplied, but the metering valves 740 of the series 754 are then optionally operated to the them to dispense or not to dispense reagents supplied. The 754 Outgoing lines 379 form the supply lines ι η for the delivery and mixing devices 27 and 28.

For example, the reagents required for a particular test are on the inlet side of the metering valves in row 754 at the start of the series of tests. To do this, the

ι i valves 740 corresponding to the reagents required one of the series 746 to 753 and 755 to 760 and the metering valves of the series 754 operated simultaneously, so that the reagents to be used in this unti flow through them until the valves and the _> o lines 379 are completely filled with them. the Valves of the actuated series 746 to 753 or 755 to 760 then remain in the actuated position, while the 754 series metering valves are closed again. Rinsing with the reagent

:> zien ensures that in the individual valves or Any remaining water or reagent is removed from the piping, and the metering valves at the the first time you press the button, dispense the correct dose of the respective reagent.

jo After completing a series of examinations, you can the various passages 778 and 780 in the valve assembly 738 are flushed with water. For this purpose, a number of flushing valves 792 are used, which with their inlets 776 via lines 794

π are connected to a pressurized water source (not shown). The inlet and outlet passages 778 and 780 in the valve bodies of the flushing valves are individually connected to inlet passages 778 via lines 796 the valve body 740 in the two lower rows 760 and 753 of the two blocks 742 and 744 are connected. Such a use of the inlet and outlet passages 778, 780 of the flushing valves / 92 suffice five flush valves to flush the ten longitudinal rows of individual valves.

π The metering valves of the 754 open at the same time as the flushing valves 792. In this way the water can all adjoining each other Inlet and outlet passages 778 and 780 in the valve arrangement 738. the metering valves of the 754 series

; o as well as the lines 379 to flow through. When the rinsing is finished, the rinsing and

Dosing valves 792 and 754 closed again in preparation for the following examination.

The programmer has various options for carrying out the desired examinations open minded. These are at least partially determined by the type of examination to be carried out. For A normal serum chemical test can use the reagents in the manner described above are added, whereupon the sample glasses 33 each one when passing under the removal head 27,28 a certain amount of the test liquid obtained is taken.

In addition 5 sheets of drawings

Claims (1)

Patent claims: 1. Device for preparing a number of physiological fluids for analysis, with - a first conveying device for sample containers, - a second conveyor device for reaction vessels, - a transfer arm through which successively Samples can be taken from the sample containers and transferred to successive reaction vessels are transferrable, and - a device for adding at least one reagent,