DE2237263B2 - Analyzer for the automatic testing of samples - Google Patents

Description

The present invention relates to an analyzer for automatically testing samples according to the Preamble of claim 1. In the analysis device, the change in the optical characteristics found a sample, e.g. B. in the determination of prothrombin times.

The population is increasingly entitled to knowledgeable help in solving individual medical problems. This factor, combined with the ever increasing level of medical knowledge, has resulted in a large increase in the number of tests of various types performed as part of a diagnosis or observational procedure. The lack of trained personnel to carry out these tests plays an important role here. As a result of the increase in the demand for such services, the cost of performing them has increased. Thus, not only is it difficult to obtain qualified personnel to perform such tests, but the cost of these services prevents them from being performed more frequently and, even under the best of conditions, the human factor must always be taken into account, thereby increasing the possibility of the test is performed imprecisely or the result is inexactly determined.

This results in an increase in the need for analog devices for carrying out such experiments in a cheap way, the devices should be operable by relatively unskilled personnel and Should exclude inaccuracies due to human error.

Such analyzers have been proposed in large numbers has been, for example, in US Pat. No. 25 CO 107, which is generically assumed. In this prior art stationary heating elements are used to the sample cells on the

ίο bring the necessary incubation temperature. this happens in that the sample cells in a turntable conveyor on the stationary heating elements to be led by. The heating elements consist of individual heating coils, which is particularly disadvantageous

1 'it is considered that such heating elements or spirals can assume different temperatures, as a result of which inaccurate heating of the individual samples is possible
Proceeding from this, it is that of the present one

μ The underlying task of the invention, this warming up to improve the samples by a more precise and nevertheless faster heating of the samples possible is made.

According to the invention, this object is achieved by the features of the characterizing part of the patent claim 1 solved

Because an elongated heating block is provided on which one or more heating elements and temperature sensors can be arranged, the block can be kept very precisely at the desired temperature a substantially uniform temperature distribution in the thermally conductive block is achieved. In addition, the block ensures that all sample cells placed in the block are heated to the same final temperature.
Since the sample cuvettes are housed in a turntable conveyor and the block largely encloses the sample cuvettes during heating in order to achieve a better temperature transition, the block is arranged so that it can be moved in relation to the sample cuvettes in order to create space for the further indexing of the turntable conveyor.

The novel heating device for the generic analysis device consists of an arched, heat-conducting block which is formed from a material such as aluminum and can be moved into or out of the path of movement of the sample cells. The block has a large number of recesses to accommodate the individual sample cells and is provided with an electrical heating element. An electromagnet is used to move the block to the sample cuvettes or to move it away and is operated in connection with the drive for the turntable conveyor in such a way that when the turntable is indexed, the block is pulled out of the path of movement until the setting process is completed, whereupon the The block moves back towards the sample cuvettes = The sample cuvettes are tightly enclosed by the block and thus uniformly heated to the desired temperature.

An embodiment of the invention is explained with reference to the figures. In the drawings shows

F i g. 1 shows an overall view of the analysis device which is essentially arranged in a housing

F i g, 2 a plan view of the turntable conveyor and other parts of the analysis device,

3 shows a vertical section approximately along the line 7-7 in F ig. 2; and

4 shows a vertical section approximately along the line 8-8 in Fig. 2.

The analyzer is used to carry out and record the results of prothrombin tests or Also suitable for other similar experiments when the device is used in conjunction with a prothrombin time experiment is described, it is of course not limited thereto.

Prothrombin time experiments measure the clumping time of blood plasma and can be carried out either with or with two reagents can be performed. When carrying out the prothrombin emergency tests, a plasma sample both calcium chloride solution and thromboplastin supplied in a single-reagent experiment the calcium and the thromboplastin are combined and a desired amount of the combined Solution introduced into the sample. The one-reagent experiment is sufficient for many purposes. Where j? But the Stability of the thromboplastin is important, e.g. B, if the experiments are carried out at irregular intervals or in large batches, it is better to keep the thromboplastin and calcium chloride solution separate for the stability of the To extend thromboplastin.

The device is described here specifically in connection with the two-reagent version, which is a larger Number of systems required than the one-reagent trial.

A conveyor 24 is charged with cuvettes which contain the plasma samples to be examined and the The conveyor is automatically gradually moved from a starting point to a first reagent addition station 320, where the first reagent is added at room temperature and mixed with the sample. When the conveyor is advanced step by step, each subsequent sample receives the first reagent at the Reagent addition station while the samples that have already received the first reagent are transferred to the incubation or a heating station where each sample is heated to a predetermined temperature before it is advanced into a second reagent addition station 322. When one sample the second When the reagent addition station is reached, the second reagent is heated to the required preparation temperature vigorously supplied and mixed with the sample, whereby a time measurement is started. To An optical test system represents a change in the optical density of the sample as a result of the formation of fibrin strands the change is fixed and the timer stops, whereupon the result is printed out and the The turntable is set to examine the next sample. The optical inspection system is first switched off so that the turbulence generated by the forceful injection of the reagent does not affect the measurement result to flow in.

An overall view of the analyzer is shown in FIG. 1 and includes a housing 20 with a control panel 22. A turntable conveyor 24 is generally flush with the top of the housing 20 and is used to incrementally advance a series of samples through the various stations. The top of the housing JQ also contains two containers 26 and 28 which hold different reagents which are used in the two-reagent experiment.

Each container is a reagent pipetting system 30 or

32 assigned, each with a volume adjustment button

33 and a pipette 34 includes

The housing 20 also contains a hinged cover 41 with a cutout 36 from which a recording tape with the printed results of the experiments. There is also a knurled hand button 40 provided for moving the belt 38 out. The cover 41 can be opened to replace the tape 38

ίο be.

As in Fig. As shown in FIG. 2, the turntable 24 has a Disk 42 with a plurality of recesses 44, with the exception of 60 ° around the entire circumference are provided. In the illustrated embodiment sixty recesses are provided and the disc 42 is provided with reference numerals 46, each Identify recess 44. The recesses accommodate cuvettes or containers, which soft samples to be examined.

The disk 42 is fastened to a mounting plate 50 by means of screws, the dimensions of the disk 42 and * is provided with a cap 52 to cover the screws. The resulting assembly is mounted on a shaft 54 which carries a large, driven gear 58 which is in engagement with a drive pinion 60 (Figure 2) which is on the Shaft 62 of an electric motor 64 with built-in reduction gear is attached The arrangement is so that starting the engine at the same time the disk 42 in Fig.2 in the counterclockwise direction in Rotation sets

On the shaft 54 a hub is attached which in turn carries a coding plate 74 the printed Switch segments 76 (Fig. 2) on their upper surface has the encoder plate 74 rotates with the turntable 24 and by the formation of the switching segments 76 a binary coded signal is obtained in a known manner, which indicates which of the recesses 44 has entered the optical test system around the sample number related to the test time. For this purpose there is a on the underside of the turntable electrically isolated bracket 78 is provided, which in turn has a number of downwardly projecting electrical Brushes 80 which act on the Schaitregmenten 76 to the information regarding the To record samples.

In addition to the drive pinion 60, the shaft 62 carries a timer cam disk 82 which, as shown in FIG. 2 is formed and shown with shift levers 84 and

so 86 of microswitches 88 or 90 is engaged. The microswitch 88 or 90 can be part of a conventional Be engine control system.

The reagent holding containers and the associated magnetic stirring systems are shown in FIG. 2 indicated however, their exact training is only briefly discussed.

Two reagent containers 26 and 28 are used which are similar to each other, except that the reagent container 26 is equipped with a heating element and a control, not shown , for maintaining the contents of the container at a desired temperature. At the same time, a magnetic stirring system is assigned to each reagent container, the stirring element of which is arranged in the reagent container and is magnetically coupled to a motor-driven permanent magnet arranged outside the container. The pipettes 34 can be moved into the corresponding container 26 or 28 in order to

take up the reagent from these and deliver it to the station 320 or 322, where it is dispensed into a cuvette containing a sample in the turntable 24. A cam drive for the two reagent pipetting systems 30 and 32 is provided for this purpose. He causes the necessary movements of the pipetting system between the reagent container arrangements and the test stations 320 and 322.

The warming or incubation system is illustrated in FIGS. 2, 3 and 4 explained. It owns one elongated thermal block 270. which may be formed from a material such as aluminum. Because of the circular path through which the sample cuvettes are moved, the block 270 is arc-shaped (! · 's g. 2) and. As shown in FIG. 3, it includes a plurality of upwardly opening recesses 272, which lie under the disc 42 which receives the turntable 24. The recesses are designed so that seal the lower part of a sample cell and in order to ensure easy insertion of the same, they are inclined towards the outside L-running upper edges 274 provided.

The block 270 is arranged in a channel-like housing 276 so that it can be moved up and down. During the Rotation of the turntable 24 shifts the block 270 downward in the channel, so the samples cuvettes containing can freely migrate over the upper surface of the block 270. When the turntable 24 stops, the block 270 is moved upwards, so that cuvettes for heating in the recesses 272 be included. To achieve such movement, there is a down in the center of block 270 protruding part 278 is provided which extends through a bushing 280 and with the core 282 one Electromagnet 284 is connected. The arrangement is such that when the solenoid 284 is actuated, its core 282 is moved downward from the position shown in FIG. 3 to lower the block 270 move. A coil spring 286 wraps around to return the block 270 to its raised position core 282 to exert an upward biasing force against part 278.

Mine exact setting of the block 270 in the .ingehoben position takes place by adjusting a adjustable stop ring 271 on the extension 290 of the part 278. The stop ring 271 has such a diameter that it allows the passage through the Bore of the socket 273 on the electromagnet 284 prevented. When the stop ring 271 at the Extension 290 is attached by means of a set screw. becomes the upward movement of block 270 at the Resetting limited by the spring 286 as soon as the ring 271 comes into contact with the bush 273. When the block 270 is in its raised position, the recess 272 is in the station 322 arranged so that if a sample cuvette is contained therein, this slightly above the surface of the Disk 42 is raised. To this end, recess 272 at station 322 is not as deep as that remaining recesses to lift the cuvette over the turntable 42 only at station 322.

Raising the sample cuvette over the surface of the disk 42 mechanically isolates the cuvette from the Disk 42 and prevents any movement transmitted to the disk or an impact on the sample cuvette which causes changes in the optical density of the plasma sample and thus can influence the test result of the optical test system.

When moving down through block 270 and out of the path of movement of the kiiveiten, should this can be done quickly while moving in> the opposite direction to contact with the Cuvettes this movement should take place much more slowly, so that the block 270 in the upward movement does not strike against the underside of the cuvettes arranged in the turntable 24. To this end ι »connects a lever arrangement (shown schematically at 288) the lower end of the extension 290 of the Core 282 with a unidirectional shock absorber 292 of conventional design. The shock absorber 292 includes a check valve. which is connected to a compression chamber, while the Lever assembly 288 is so connected to the piston of the shock absorber. that when the Piston in the compression chamber the gas is not compressed, d. H. i let it out through the valve Chamber can exit. During the upward movement of the piston as a result of the bias by the However, spring 286 closes the check valve and gas flow into the compression chamber is through a adjustable throttle determined so that a r> partial vacuum builds up, which increases the speed of the Delayed upward movement. As mentioned above, the slow upward movement prevents an impact and ensure precise alignment of the bottom of each cuvette with the associated recess 272. In order to transfer heat to the samples through the block 270, strip-shaped silicone rubber heating elements are used 294 attached to the underside of the block 270, which is supplied via electrical lines 296 to the heating elements 294 by a ι- '. Bore 298 are guided, which through a sleeve 300 is electrically isolated. Foam pads 299 are between the heating elements 294 and the housing 276 inserted to thermally insulate the housing and to create additional cushioning when the block ■) (! 270 touches the housing 276.

In order for the samples to be heated to a predetermined temperature, a temperature sensing element, e.g. B. a thermistor 302 attached to block 270 · '<. A protective tube 304 extends downward from the block 270 and encases it slidably through a bore 306 for connecting a control circuit for the strip heating elements 294.

Like F i g. 3 shows is a plurality of recesses

'· <■ provided, the number of which in connection with the

Speed of the turntable 24 ensures. Adjust each sample to the desired heating temperature

before it is transferred to station 322

where the optical inspection system is located.

ϊ5 The design of the optical test system and the Cuvette scanner is shown in FIGS. 2 and 4 can be seen.

With regard to the cuvette scanner it should be noted that

a reagent can be added at each of the two stations 320 and 322 (FIG. 2). But if not

fco cuvette is present. should the reagent not be dispensed and to ensure this, each of the

Provide stations with a cuvette scanner. As in Fig. 4, each cuvette scanner includes one

Lamp 324 a, which is in a horizontally extending

"Bore 326 of the housing 276, which is in a

Schmaien horizontally directed opening 328 ends which lies on the channel delimited by the housing. Aligned with the opening 328 on the opposite

lying side of the channel, a similar opening 330 is provided, which is located in front of a bore 332 , which through a photosensitive element. z. B. a photo resistor 334 is completed. / wipe hole 330 and photoresistor 334 is! a diaphragm 336 in the form of a disk with numerous parallel bores is provided, which is pressed against the end of the bore 332 by a small spring 338 which is inserted between the photoresistor 334 and the diaphragm 33fi.

The optical inspection system is only provided at station 322 . There the housing 276 is seen with a receiving bore 350 for a second light source which can receive a lamp 352 in which a lens 354 is integrated into the lamp in order to generate essentially parallel light beams. The bore 350 ends in an opening 356 with a slightly smaller diameter and between the opening 356 and the lamp 352 a high frequency filter 35S is inserted. In prothrombin time experiments, the filter 358 can be a red filter such that it does not allow the passage of wavelengths below 600 nanometers, so that the effect of changes in the blood plasma is eliminated as a result.

Aligned with the opening 356, but on the opposite side of the channel, a similar opening 360 and a second diaphragm 362 designed as a disk with numerous parallel bores are provided. The screen 362 lies in a bore 364 which is closed at one end (at 366) and encloses a diffuser in the form of a section of a light tube 368 . The function of the diaphragm 362 is also here to prevent inaccurate scanning of light changes as a result of changes in the ambient light, for a photosensitive element such as a photoresistor 370 is located in a bore 372 which is arranged transversely to the bore 364 . so that the photoresistor 370 is arranged on a cable of the light tube 368 . This arrangement prevents local changes in the total beam of the light passing through the sample from resulting in an incorrect evaluation of the lump formation. The control for the optical test system uses logic which are known in many ways from electronic techniques and are therefore not described in detail since it is within the skill of the person skilled in the art to create a suitable circuit to achieve the special functions.

To do this, 3 sheets of drawings

Claims (3)

Patent claims: 1. Analyzer for automatic testing of samples, with a conveyor for receiving a number of sample-containing containers and for conveying them along a track, with a test station on the track, with a stepping device for stepping the conveyor for successive introduction of each one containing a sample Container in the test station, and with a heating device for heating the samples in front of the test station, characterized in that the heating device has a heat-conducting block (270) with recesses for receiving at least a portion of the container containing the samples, that the block has a heating element (294 ) and a temperature sensor (302) are assigned, and that the block (270) is connected to a drive which is used to move the block out of the path before the conveyor (24) is whitened or to enter the path when the conveyor is stopped the stepping device for the conveyor erer (24) is coupled 2. Analysis device according to claim 1, wherein the conveyor is designed as a turntable, characterized in that the block (270) is made of aluminum and is arcuate. 3. Analysis device according to claim 1 or 2, characterized in that the drive for retracting and extending the block includes an electromagnet (282, 284) and a FeJerano: Jnung (286) claiming the block in the direction of the web, and one in a directional damping device for slowing down ?; the entry of the block into the path (292) is provided