HU194046B - Sample holding device for discrete analysis of liquid materials to be analysed - Google Patents

Abstract

In the case of a sample carrier for the discrete analysis of liquid analysis assays with the aim of increasing the accuracy of measurement and the range of application of photometric methods, the object is to develop a sample carrier which can be used as a measuring cuvette and which ensures consistent layer thicknesses for all the samples in it, which can be tempered and easily cleaned is. The object is achieved according to the invention by virtue of the fact that a central body containing a cavity is delimited at its base by a lower terminus and by an upper terminator and that the terminators each have surface areas lying in common planes, which are at least close to basic areas. or deck area.

Description

FIELD OF THE INVENTION The present invention relates to a sample holder for discrete (individual) analysis of liquid analyte materials.

The invention is advantageously applicable to chemical, enzymatic and immunological analyzes in the fields of biological research, clinical chemistry and laboratory diagnostics, for example analytical tasks in the field of animal and plant production, analytical tests in the field of immunobiology and tropical health. Such a sample holder is predominantly used where large numbers of samples are subjected to photometric analysis (chlorometric, fluorimetric, turbidimetric, nephelometric):

Known microtiter plates consisting of sample containers arranged in a matrix form have the advantage that they can be used to prepare sample layers more readily and to select freely the thickness of the sample as determined by the volume of the sample.

However, these disks have the following disadvantages:

The optical path of light rays is not constant due to the various optical effects on the free surfaces bordering the light in the various cavities.

In addition, the various adhesive bonds of the material to be analyzed on the vessel wall, the volume errors and the different geometrical parameters of each vessel affect the radius of the photometer, the accuracy of the film thickness and thus the accuracy of the analysis results.

This significantly reduces the field of application of the microtiter plate.

In contrast, microcuvette-type sample holders, such as the device described in DNK-A-107,783, provide the ability to accurately determine the film thickness and thus allow high accuracy photometric measurement of very small amounts of sample.

One disadvantage of these cuvettes is that, due to the lack of lateral delineation of each sample site, great care must be taken when applying detergent solutions with low surface tension. In addition, the layer thickness is limited to a maximum of 2 to 3 mm, so that only samples with low absorption coefficients can be tested for colorimetric and turbidimetric measurements.

The common disadvantage of both types of cuvettes is that they are difficult to temper and thus cannot be used for enzymatic measurements.

It is an object of the present invention to provide accurate colorimetric, fluorimetric nephelometric and turbidimetric measurements for the discrete analysis of a large variety of samples arranged in a single analyzing unit and to permit the wide application of these measurement methods.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a sample holder capable of receiving liquid samples and also serving as a measuring cuvette, which is defined for ease of handling, is advantageous for photometric analysis and provides the same layer thickness for all samples in the sample holder.

SUMMARY OF THE INVENTION The object of the present invention is to provide a discrete analyzer for discrete analysis of fluid to be analyzed, with parallel running boundary planes, having a uniformly spaced, uniformly closed cavity at each end, by providing a central body containing the cavities which - and its top plane is defined as a boundary plane of the cavities, defined on its base plane by a lower closure body and an upper closure body by means of recesses on the side of the upper closure body towards the central body which surround surface areas of optically permeable material the number and arrangement of the surface regions correspond to and are at least partially covered by the cavities, the lower closure body having surface elements in the same plane sealing the cavities and The common planes parallel to the base and top planes are adjacent to the planes assigned to them.

Depending on the surface tension of the materials to be analyzed, there are two versions of the upper barrier body.

In the first embodiment, the surface regions delimited by the recesses touch the material to be analyzed in the cavities by spacers between the central body and the upper barrier, so that they are only laterally limited by air between the central body and the upper barrier.

The second embodiment comprises pins made of optically permeable material as surface areas delimited by the recesses which partially extend into the cavities by lateral play.

When a closure body according to the first version is used, it is preferable to have recesses in the top plane of the central body which surround the cavities at a given distance and lie substantially in the recesses formed in the upper closure grid.

For ease of cleaning, the lower closure body comprises an optically permeable, elastic material and a pressure plate which fits within a profile in the region of the base plane of the central body. The elastic material may be provided simultaneously with the reaction partners required for the analysis.

According to a further embodiment of the invention, cavities are formed in the form of tubes with the same length and calibrated internal diameter which are recessed into the central body and whose ends are in common planes extending parallel to the base and top planes near their respective planes.

For the temperature of the sample holder according to the invention, the central body of the heat-conducting material has further interconnected cavities which at least partially surround the hollow cylinders and are provided with at least one conduit extending outwardly through the central body. tools.

If the sample holder of the present invention is to be heated, at least the base or top bag or one of the sectional surfaces of the central body must be coated with a conductive material so that the cavities remain free.

The invention will now be described in more detail with reference to the schematic drawing. Figure 1 is a perspective view of some elements of a sample storage device according to the invention, Figure 2 is a sectional view of a top bar body designed for compounds with low surface tension, Figure 3 is a side view of a temperable central body;

194.016 * Figure 4 is a side view of a sample holder having tubes sunk into the central body.

The sample holder according to the invention, shown in Fig. 1, consists of a central body 1 having a column shape, the base and top planes 2 and 3 of which are opposed by optically permeable sealing bodies 4 and 5. The topsheet 3 has recesses 6 formed in the form of grooves 6 surrounding the cylindrical cavities 7 of the central body 1 in the form of a matrix. The base and top planes 2 and 3, respectively, form the boundary planes of the cavities 7.

Of the closure bodies 4 and 5 adjacent to the central body 1, the upper closure body 5 is provided with recesses 8 in the form of grooves which are substantially opposite to the grooves 6 and surround surface areas in a common plane. The lower closure body 4 is, for example (not shown), secured to the central body 1 by means of soluble mechanical or magnetic means or fixed.

For analysis, liquid analysis specimens are filled into the well-sealed cavities 7 enclosed by the closure body so that the convex fluid meniscus extends beyond the upper limit of the cavities 7. (The upper limit of the cavities 7 corresponds to the cover plane 3 of Figure 1.) The spacers in the cover plane 3 are dimensioned such that the latter 5 touches the fluid meniscus with the region 9 of the surface delimited by its groove 8.

Due to the zone boundaries of the grooves and as a result of the cohesive and adhesive effect, since the substances to be analyzed are bounded only by air in the meniscus, the liquid remains stable and can be avoided. At the same time, the liquid columns in the cylindrical cavities 7 have the same film thickness by their upper closure.

The sample holder is placed in a suitably designed photometer for successive or simultaneous measurements. The upper closure of the type shown in Fig. 1 forms a closure body consisting of a parallel-plate 13 and a pressure plate 14. 15 sealing elements prevent flow and mixing of samples to be analyzed.

Such a solution for bottom closure can also be applied to the embodiment shown in FIG.

By immersing the pins 11 in the material to be analyzed filled into the cavities 7, the effective film thickness of the compound to be photometrized is determined by the distance of the boundary planes 12 to the base plane 2. The possibility of lateral displacement of the pins 11 relative to the wall of the cavities 7 ensures displacement of the excess compound.

The filling height of the liquid to be analyzed should be chosen so as to avoid overflow of liquid during dipping of the taps.

By applying different upper sealing bodies 5 having pins 11 of different lengths relative to one another, different film thicknesses can be achieved with the same central body 1.

The central body 1 shown in Fig. 3 has additional cavities 16 which at least partially surround the cavities 7, which are in communication with each other (not shown) to temper the sample. The cavities 16 may be configured to pass the tempering fluid or to receive the heating and temperature measuring devices. The channels 17, 18 connected to the cavities 16 serve as inlet or outlet channels or as inlets for electrical wires. Another possibility of tempering the sample is provided by coating the base and / or topsheet or one or more cross-sectional surfaces with a conductive material which leaves the cavity free.

In Figures 4a-d. In Figures 1 to 4, the cavities 7 are formed in the form of tubes 19 sunk into the central body 1, whose ends 20, 21 always form a plane not parallel to the base and top planes 2 and 3, not shown in the figure. The common planes are either coincident with, or offset from, the base and top planes 2,3 (b-d). While in the embodiment of Fig. 4a grooves 6 are machined into the topsheet 3 as shown in Fig. 1, in other embodiments (Figs. 4b-d) the effect corresponding to these grooves 6 is provided by the elevation of the pipe ends 21 to the topsheet 3.

By displacing the plane formed by the tube ends 20 with respect to the base plane 2, a profile is formed which allows the use of a lower closure body consisting of a film 22, optically permeable, flexible material and a pressure plate 23 fitted to the profile. By means of the pressure plate 23, the foil 22 is sealed onto the tubes 19 on the profile of the central body 1, where the pressure plate 23 is mechanically or magnetically secured.

This solution allows the sample holder to be easily cleaned by removing the foil 22 and replacing it with a new foil. If necessary, it is also possible to slow the film 22 on the side facing the central body 1, at least on the sealing surface of the tubes 19, with the reaction partners required for analysis.

Claims (9)

A sample holding device for discreet analysis of liquid analyte materials, having identical cavities closed at one end and formed in a defined arrangement, wherein the cavities have parallel boundary planes, characterized in that a central body (1) comprising the cavities (7) the upper plane (2, 3) being bounded by the lower plane of the cavity (7), with its lower plane (2) and its upper plane (3) and its upper plane (4), whereby the central body (1) The recesses are formed on its side facing towards the surface areas (9) of optically permeable material in a common plane, the number and arrangement of which correspond to the cavities (7) and which at least partly cover the latter (4). ) contains common sikan-lying surface elements closing the cavities (7) and the common planes They extend at least near the elongated planes, parallel to the base and top planes (2, 3). A sample holding device according to claim 1, characterized in that the recesses are surface areas (9) delimited, for example, by grooves (8) by spacers (10) between the central body (1) and the upper closing body (5). (7), so that the samples to be analyzed in the part between the central body (1) and the upper barrier body (5) are only laterally bounded by air. 194 046 The sample holding device according to claim 1, characterized in that the surface regions delimited by the recesses are formed as pins (11) of optically permeable material which partially extend into the cavities (7) by means of lateral play. Sample holder according to claim 2, characterized in that recesses, such as grooves (6), are provided in the plane of the central body (1), which surround the cavities (7) at a given distance and are located in the upper closure body (5). they are essentially opposite to the recesses. 5. The mlnt retaining device according to any one of claims 1 to 3, characterized in that the lower closure body (4) consists of an optically permeable, flexible material and a pressure plate (14, 23) fitted to a profile in the region of the base plane (2) of the central body. 6. A sample holding device according to any one of claims 1 to 3, characterized in that the cavities are formed in the form of tubes (19) of the same length and calibrated internal cross-section sunk into the central body (1), the ends (20, 21) of which , which planes parallel to and at least close to the plane of the base and top. 7. A container holding device according to any one of claims 1 to 5, characterized in that the central body (1) is made of a thermally conductive material and further interconnected cavities (16) which surround the cylindrical cavities (7) in at least one part thereof. they are provided with an outwardly extending passage (18) through the central body and are provided with means for measurable and adjustable stretching. 8. Figures 1-6. A sample holding device according to any one of claims 1 to 5, characterized in that at least 15 ', the base or top plane (2, 3) or a cross-sectional surface of the central body (1) is coated with a free-flowing conductive material of the cavities (7). Sample holder according to claim 5, characterized in that the optically permeable resilient material portion of the closure body is provided with reaction partners for analysis on the surface facing the central body (1).