DE2349927C3 - Device for optical rapid analysis - Google Patents

Description

The invention relates to a device for the optical rapid analysis of the rotary cuvette type a rotor arrangement, the cuvette rotor of which has a circular arrangement of loading cavities and Sample analysis cuvettes formed between a stationary light source and a light detector device can be passed through during the rotation, and wherein a rotor holder the cuvette rotor carries and signal generating means are arranged adjacent to the rotor holder for the passage of Display means determine which are equal in a number the number of sample analysis cuvettes provided.

From DE-OS 21 14 179 is a device known for optical rapid analysis, in which a Cuvette arrangement of a housing with laterally protruding walls and an annular one Cover is surrounded. The light penetration openings in the Lids must be aligned with openings in the housing. The magnets used as display means must be provided on the underside of the aluminum housing.

From US-PS 35 55 284 a device for optical Schncllanalyse is known, however, the The cuvette rotor shown there is relatively large and has a rather complicated sandwich-like structure glass and polytrafluoroethylene rings held together, which / wipe a: `` .steel rotor body and a flange ring provided with bolts. Such rotors are expensive and must / to avoid contamination of subsequent samples / cleaned during the analysis processes will.

The invention is based on the object of a Apparatus for optical .Schnellanalyse of the type mentioned in such a way that a small and uncomplicated structure results, troi / dem die Handling of the device is simple and Find disposable Kiiveltenroloren use can.

According to the invention, the task is mn the Features of the characterizing part of claim 1 solved.

Preferred embodiments of the invention emerge from the subclaims.

The invention is closer in the description of embodiments with reference to the drawing explained. It shows

Fig. I a plan view - partially cut - on a photometer according to the invention;

FIG. 2 is a vertical section through the photometer of FIG. I;

FIG. 3 is an enlarged plan view, the static charging side of a device in the photometer of FIG. I and 2 usable, disposable cuvette rotor is shown;

Fig. 4 an enlarged perspective. partially

Cutaway sectional view showing the static loading side of the cuvette rotor of FIG. 3 even further illustrates;

5 is an enlarged plan view of the dynamic Loading side of the cuvette rotor of FIG. 3 and 4;

F i g. 6 is an enlarged perspective, partially cut-away, sectional view showing the dynamic Loading side of the cuvette roller of Fig. 3-5 further explained.

In Figs. Ί and 2, a compact photometric analysis device is shown in plan view and in a vertical section. A motor-driven cuvette rotor holder 2 is rotatably mounted on the top of a small, generally rectangular sheet metal box 1; the rotor holder 2 has a flat, plate-like circular base 3 which is equipped with an upwardly projecting annular lip or rim 4 formed in one piece therewith in order to receive and hold a disposable cuvette rotor 5. Two or more retaining pins 6 (only one is shown, however) are arranged on the rotor holder 2 within the limits drawn by the lip 4 and come into engagement with suitable recesses in the cuvette crown 5. The pins 6 ve ^r hindem relative rotation between cuvette rotor and rotor holder, permit but extends the relatively effortless, manually taking place insertion or removal of the cuvette rotor with static (StMI- stands-JBedingungen A circular array of apertures. 7 during operation of the analyzer with high spin through the base 3 of the rotor holder, in axial alignment with corresponding sample analysis cuvettes 8 within the cuvette rotor 5. A movable photometric light source 9 generates a light beam of constant intensity which penetrates the rotor 5 at a point that corresponds to the radial positions of the sample analysis cuvettes. The light beam from source 9, indicated by a dashed line in FIG , a ribbed lamp housing Case 11 and a salt focus lens 12. A button 14 is attached to the lamp housing 11 in order to facilitate the arrangement of the lamp housing during or immediately after the analyzer function when the housing is at an elevated temperature as a result of the heat from the lamp 10.

Below the rotor holder 2 and the top of the box I is an electronic photodetector 15 of this type arranged that it receives light transmitted through the sample analysis cells 8 when these / wipe the Photodetcktor and the light source 9 pass through. The photodetector 15 has a photomultiplier tube which produces an output signal proportional to the received light intensity.

Between the photodelector 15 and the rotor hall 2 there is a movable filter holder 16 which allows the selective arrangement of a filter from a plurality of interference filters 17 in the path of the light passing through the cells 8. The filter holder 16 is secured to the vertically extending shaft 18 by means of an adjusting screw which is rotatably supported by a thrust ball bearing 19 which is fixed in the base of the retaining clip 20. The holding element 20 is rigidly attached to the box 1 and slotted so that an angular displacement of the Vilterhalterers 16 within the

Limits are possible which are necessary for aligning any filter 17 above the photodetection 15 are. At the upper end of the wilts Filierselektorknopf 22 attached so that a user can select the desired filter by hand.

As can be seen in Fig. 2, a thin-walled one is used Tube 23 as a mounting bracket for the movable Light source 9. The tube 23 is attached to the holding element 20 and is held in this by a locking screw

ίο supported and extends coaxially with the shaft 18. Immediately above the Haltec-Iements 20 is a first sleeve 24 in rotational engagement with the tube 23. A second sleeve 25 serving as a holder for the lamp housing 11 is attached to the first sleeve 24 by adjusting screw means and rotates with this. The first sleeve 24 is provided with curves 26 (only one of which is shown), with which a spring-loaded pin 27 then comes into engagement. when the light source is in its operating position shown or when - as in FIG. 1 shown in dashed lines - by 90 ° v. is turning to replace the rüior. The radial light source for aligning it with the cuvettes is achieved by loosening the locking screw 28 by sliding the sleeve 29 within the opening 30 in the second sleeve 25. An indicator plate 32 indicating the position of the filter holder 16 together with the filter selection button 12 is attached to the top of the tube 23 by adjusting screws. A spring loaded pin in button 22 engages recesses in indicator plate 32 to permit secure placement of the filter holder.

An index wheel 33, which engages with a microswitch 34, is attached to the bottom of the shaft 18. The rotation of the shaft 13 during the filter selection causes a corresponding rotation of the index wheel and an exposure of the microswitch. This has the effect that a differently prepended potentiometer is switched into the photodetector high voltage supply circuit in order to maintain a constant signal for a cover cell which is filled with pure water. A differently preset potentiometer is used for each interference filter 17 in the filter holder 16.

⁴ "'The rotor holder and the cuvette rotor are driven by a combined servomotor-tachometer generator 35. A magnetic brake 36 acts on the rotor holder drive shaft 37. in order to have a rapid braking effect on the cuvette rotor / to increase the

^r ' ⁿ sample and reagent mixture in the cuvettes. Using the magnetic brake 36, the rotor speed was reduced from approximately 2000 revolutions per minute to a standstill in less than one second.

^{5l .Synchronization} signals are through rotor and Küvetlen-Synchronwationsdetektoren 38 and 'v. 39 generated. A similarly designed detector 40 generates a signal for activating the automatic photomultiplier voltage line (not shown).

^wl represents). Signals are generated when appropriately spaced openings in the rotor holder pass through the detectors and allow the front. a small tungsten filament lamp 41 in the detector above the rotor holder a photodiode 42

^{reached b5} , which is arranged in the detector below the cuvette holder. The detector 39 shown in section in FIG. 2 is representative of all three detectors. A circular rail 44 for arranging the

Detectors partially encompasses the cuvette holder 2. The synchronization can be achieved in that one moves the detectors along the rail 44 until the correct synchronization is achieved, whereupon they then on Box or housing 1 can be fixed by locking screws.

As shown in FIG . Rinzclöffnunpcn 46 and 47 cause b / w in the detectors 38. 40 the generation of signals with each revolution of the rotor holder.

The temperature of the Küvetlcnrotors is by a Thermistor monitored within the retaining pin 6, which is so arranged. that he / wipe the two Cuvctlcn on a common radius with the circle arrangement of the Cuveitcn. Of the TliC-i iiiniui im fei nci iiiih.1 iialij des Siifies 6 lieiari arranged that it is axially centered! lies within the rotor 5, Such an arrangement causes a close Correlation between the thermistor output variable and the temperature of the cells. In electrical Slip rings 48 connected to the thermistor are provided on the rotor holder to prevent the Allow reading of the signal from the thermistor / u. The room temperature as well as the speed are read on a measuring device 49 attached to the top of the analyzer housing.

In the Γ i g. 3 and 4 is the static (stationary) l.adescite of the disposable cuvette rotor 5 in. used in the analyzer of FIGS. 1 and 2 Top view b / .w. shown in a perspective sectional representation. The structure of the rotor is a layered construction with a central, preferably opaque, plastic disk 51. which is sandwich-like between outer transparent disks 52 and 53 lies, line circular arrangement of axially extending Openings are formed in disk 51, these openings serving as sample analysis cuvettes 8. Concentric Ring arrangements of sample and reagent I .adohnhlrälimi-n S4 MnH Si cinH on pinr> r 1 · I.llatk

arranged along radii that run through each cuvette. As shown in Figure 4, the cargo cavities 54 and 55 are formed by indentations in the central disc 51 and terminated by the outer disc 52. The cargo ports 56 and 57 are in alignment with each cavity in the respective arrays of cargo cavities Static loading or introduction of reagents and samples into the loading ports is possible using a hypodermic syringe or automated dispenser. Radial fluid communication is provided by small connecting channels 58, 59 between respective sets of loading cavities and cuvettes. A central loading inlet 60 extends by disks 51 and 52 and allows dynamic (ie, while moving) loading (introduction of liquid)

using the dynamic loading side of the rotor, which is discussed below with reference to FIG. 5 and 6 will be described.

In FIGS. 5 and 6, a top view and a perspective view of the dynamic loading cables of the rotor 5 are shown. The loading inlet 60 ends in a distribution chamber 61 which communicates with cuvettes 8 through radially extending distribution channels 62, the capillary size bcsil / s. to keep the liquids in the cuvette when the rotor is not rotating. The intersection of the channels 62 creates a sawtooth or jagged knot effect. a guaranteed in the substantial uniform distribution of the liquid in the enlspre chendcn channels when the rotor ', rotates and liquid is injected through 60 in Einlal3 di distribution chamber.

Various methods for introducing the sample and reagent liquids into the rotor 5 are possible. Hei a procedure are in the static

/.USW1IIU CIII / L'lltC f ItMJCII UIIU

The corresponding loading cavities 54 and 55 are introduced. This is achieved by introducing the samples by volume of reagents through corresponding loading openings 56 and 57, which gives greater flexibility

.ι possible when using this method, since ver Different combinations of samples and reagents are possible in each satellite / loading cavity. You. Static charging effects following the rotation of the rotor transport the samples and reagents

in gene / liquids in the corresponding cuvettes / uir Purposes of photometric analysis.

Another charging method can be used there where either a multitude of reagents mi a single sample or a single reagent with

Ii a large number of samples are to be reacted. In in this case, the only sample or reagent will pass through the charge port 60 into the orbital Rotor injected or injected and evenly distributed over the cuvettes. The rotor then becomes a standstill stanc

■ »" brought and individual samples or individual Rcagen zicn are introduced from the static l.adescite of the rotor.

Another loading method uses the pre-loading and lyophilization of various reagents ii, the

4) corresponding cuvettes. If a photometric Analysis is to be carried out, clic lyophilized reagents by pre-injection Solubilized water or a buffer medium in the rotating rotor in the manner described above

A sample fluid can also be introduced dynamically in order to obtain multiple chemical analyzes on a single blood sample .

The rotor can also have a different number of

Sample analysis cuvettes aFs just have the 17 shown. The special arrangement of the channels for the static and dynamic charging can also be modified and / or partially omitted, so that only static or dynamic charging is possible

bo would be.

For this f sheet drawing «*

Claims (8)

Patent claims: 1. Apparatus for optical rapid analysis of the rotary cuvette type with a rotor arrangement, the cuvette rotor of which forms a circular arrangement of loading cavities and sample analysis cuvettes which can be passed between a stationary light source and a light detector device during rotation, and wherein a rotor holder carries the cuvette rotor and signal generating means adjacent to the rotor holder are arranged to determine the passage of display items, which are provided in a number equal to the number of sample analysis cuvettes, characterized in that the rotor holder (2) has a flat circular base (3) with an upwardly projecting, integrally arranged on the base retaining rib (4), within the radial limits of which the cuvette rotor is removably arranged. while outside the retaining rib {* ', in the base (3) a circular arrangement of axially extending openings (45, 47} is formed, which form the mentioned display means. 2. Apparatus according to claim 1, characterized by two or more retaining pins (6) on the Rotor holder (2) are arranged within the limits drawn by the rib (4) and with matching recesses in the Küveitenrotor (5) can come into engagement. 3. Device according to claim 2, characterized in that that i-> a pin protruding upwards for temperature measurement of the cuvette rotor serving thermistor is arranged. 4. Device according to one or more of the preceding claims, characterized in that the upwardly projecting pin is arranged in a radial position. which corresponds to the radius of the first row of axially extending openings and the sample analysis cuvettes, and wherein the thermistor is so positioned within the pen. that it is centered axially within the movable Küveiicnrotors when the Roto ^r on the basis of within the Gren / .cn the rib is arranged. 5. Device according to one or more of the preceding claims, characterized in that that the removable cuvette rotor has first and second sets of radially oriented load cavities (54, 55) in concentric ring arrangements, and that connecting channels (58, 59) to Creation of a central passage of a flow medium available. 6. Apparatus according to claim 5, characterized in that the geschichtcl built up cuvette rotor a small, opaque slice sanclwichariig between first and / or partially transparent panes, said sentences of first and / or wide cavities are depressions in the opaque disk, and where Loading ports (56,57) through the first clear disk (52) in axial alignment with the respective ones Loading cavities (54,55) run. 7. Apparatus according to claim 5 and / or 6, characterized in that the cuvette rotor a central distribution chamber (60) and a plurality of distribution channels having a Establish a connection between the distribution board and the corresponding cuvettes. 8. Device according to one or more of claims 5-7, characterized in that each of the distribution channels (62) with adjacent distribution channels (62) at an acute angle intersects so that a serrated circumference is formed around the distribution chamber (61) (Fig. 5).