EP1255987A1

EP1255987A1 - Device for analyzing substances by means of thin layer chromatography

Info

Publication number: EP1255987A1
Application number: EP01901104A
Authority: EP
Inventors: Rolf GÜLLER; Séraphin MUNCH; Philippe Jablonski; Josef Schröer
Original assignee: Chemspeed Ltd
Current assignee: Chemspeed Technologies AG
Priority date: 2000-02-14
Filing date: 2001-01-29
Publication date: 2002-11-13
Also published as: US20030013187A1; WO2001059445A1; US6709584B2; AU2001226613A1

Abstract

The invention relates to a device which is used to analyze substances by means of thin layer chromatography, comprising a solvent tub (1) with two channels (11, 12). Two wall plates (4, 5) are mounted in the solvent tub (1), enabling thin layer plates (2, 3) to be arranged in an upright manner inside said channels in a slanted position with respect to the horizontal level thereof. The substance which is to be analyzed can thus be dropped onto or applied to the thin layer plates (2, 3) from above and a solvent can be fed to the channels (11, 12) from above at a supply point (111, 112). Upward migration of the constituents of the substance to be analyzed can thus commence without changing the position of the thin layer plate (2, 3).

Description

Device for substance analysis by means of thin layer chromatographic

graphy

The present invention relates to a device for substance analysis by means of thin layer chromatography, as defined in the preamble of independent claim 1.

In substance analysis using thin layer chromatography, the substance to be analyzed is dripped or applied onto a thin layer plate, a support plate and a thin layer of a functional substance arranged thereon, for example silica gel, C ₁₃ , C ₈ , C ₄ , C ₂ , C _S H ₅ , NH ₂ , A1 ₂ 0 ₃ , paper (cellulose), starch, etc., has. The thin-layer plate is then placed in a suitable solvent or generally a mixture of solvents, for example hexane, hexane and ethyl acetate in a ratio of 1: 2, cyclohexane and dichloroethane in a ratio of 2: 1, etc., which, owing to the Capillarity of the thin layer migrates upwards and takes the dripped or applied substance to be analyzed or, if necessary, various components thereof upwards. Since different substances or components migrate upwards at different distances, the substance or components can be inferred from this, in particular if a reference substance has also been applied.

Up to now, substance analysis has mostly been carried out by hand using thin-layer chromatography. The thin layer plate laid flat on the laboratory table and a drop of a reference substance and a drop of the substance to be analyzed or a drop of different substances to be analyzed placed side by side on a starting line on the thin layer plate, for example with a pipette. The thin-layer plate is then placed by hand in a trough with solvent, so that the lower part of the thin-layer plate is wetted and the solvent can migrate upwards, taking the applied substances or possibly various components thereof upwards. So that the solvent does not evaporate too quickly on the thin-layer plate, the solvent tray and thin-layer plate are covered with a tray cover. Before the solvent reaches the top of the thin-layer plate, it is removed from the solvent tray again.

The hand analysis of thin-layer chromatography has the disadvantage that it is relatively complex and requires the presence of a chemist or laboratory technician, which can be particularly problematic in that the upward migration of the solvent can take several hours and therefore the thin-layer plate may be in the middle of the Must be removed from the solvent tray at night so that the result image does not become blurred.

These disadvantages can be partially avoided by means of the automatic developing chamber "Automatic Developing Charnber ADC" from Camag, CH-4132 Muttenz, which has a solvent tank with a solvent channel, a tank cover and means for automatic feeding and removal. tion of solvents. The thin-layer plate provided with the substance to be analyzed is placed in the development chamber, the development chamber is closed and finally solvent is automatically added and removed again. However, the substance to be analyzed must still be dripped or applied onto the thin-layer plate outside the automatic development chamber and the thin-layer plate must then be gripped and placed in the development chamber.

In view of the disadvantages of the previously known methods and devices for substance analysis by means of thin-layer chromatography, the invention is based on the following object. A device for substance analysis by means of thin-layer chromatography of the type mentioned at the beginning is to be created, which enables the substance analysis to be carried out in a simplified, automated manner.

This object is achieved by the device according to the invention as defined in independent claim 1. Preferred design variants result from the dependent patent claims.

The essence of the invention is that a device for substance analysis by means of thin-layer chromatography, with a solvent trough that has at least one solvent channel, has means that make it possible to arrange a thin-layer plate at an angle to the horizontal in the solvent channel, so that the substance to be analyzed by can be dripped on or applied to the thin-layer plate from above and the solvent channel attached to a solvent. telzuführstelle solvent can be supplied so that the upward migration of components of the substance to be analyzed can be started without having to change the position of the thin-layer plate.

Because the thin-layer plate is arranged obliquely to the horizontal, its position does not have to be changed during the entire time, which simplifies the entire process sequence and allows it to be automated without great effort. Automation is also facilitated by the fact that the material to be analyzed can be supplied from above and can therefore be operated by commercial robots that can be moved in one or two horizontal and vertical directions. Since these robots generally also carry out steps for the upstream and downstream processes, it is of great advantage to also use them for substance analysis using thin-layer chromatography, which can also be carried out on-line.

In a preferred embodiment variant, the solvent can also be supplied from above.

The optimal angle α between the thin-film plate and the horizontal is between 40 ° and 50 °, preferably 45 °. At such an angle, on the one hand, the substance to be analyzed can simply be dripped on or applied from above and, on the other hand, the thin-layer plate can be suitably wetted in the lower part with solvent, which can migrate well upwards together with the substance or components to be analyzed. Generally, an angle α between 20 ° and 80 ° and even between 5 ° and 85 ° is suitable net, while an angle α less than 5 ° and greater than 1 ° or greater than 85 ° and less than 89 ° is less suitable, but is still possible.

The solvent trough advantageously has two or more independent solvent channels, at least two thin-layer plates preferably being able to be arranged in a solvent channel. Ten or more solvent channels can also be implemented, each feeding a thin-layer plate with solvent. A variety of substances can then be analyzed with two or more different solvents.

In a preferred embodiment variant, the or each solvent channel is inclined toward a solvent suction point, which preferably corresponds to the solvent supply point. This makes it possible not only to supply solvents at a single point, but also to suck them off again at a single, preferably the same point. The feeding process starts with the addition of the solvent, while it is ended with the removal of the solvent.

In the normal case, the device according to the invention also has a tub cover which largely closes off the solvent channel or channels and the thin-layer plate or plates from the outside. In this way, a saturated atmosphere can be generated which prevents the solvent (s) from evaporating too quickly, in particular at a high vapor pressure at the analysis temperature. The trough cover advantageously has holes, slots or an open surface at the top, which allow the supply of solvent and the dripping or application of substances to be analyzed onto the thin-layer plate or plates through the trough cover, the holes, slots or the open area is preferably closed with septa or a septa plate. The substances and solvents to be analyzed can thus be supplied from above with the solvent pan covered, the septa or septa plates, if any, ensuring a tight cover.

Normally, the device according to the invention also includes an addition device, which preferably comprises a hollow needle that can be moved vertically and in at least one horizontal direction, with which substances to be analyzed can be automatically dripped or applied onto the thin-layer plate or plates, and solvents can be supplied automatically at the solvent supply point or positions and can be suctioned off at the solvent suction point or points. The addition device enables automatic substance and solvent handling, so that after programming the control of the addition device, the entire process can be carried out without the intervention of a chemist or laboratory technician.

In a preferred embodiment variant, the device according to the invention has a reagent matrix, which comprises receiving holes for reagent containers and through-holes between them, through which an addition and removal tool for adding and removing add analyzing substances and solvents is feasible. Reagent containers with substances to be analyzed can then simply be arranged in the receiving holes and for analysis a substance to be analyzed can be removed from the reagent container and applied through an addition hole to a thin-layer plate arranged underneath. Solvent is normally removed from separate, larger containers, but could also be added differently instead of using the addition and removal tool mentioned, for example by plucking, opening a valve, etc.

Advantageously, means are provided for visualizing components of the substance to be analyzed which have migrated upward and which preferably comprise a UV lamp and / or means for spraying with chemical reagents. The analysis result can thus be made directly visible.

In a preferred embodiment variant, the device according to the invention is also provided with means for determining the point in time at which existing solvent is to be removed from the solvent channel or channels, which preferably comprise a CCD camera. The optimum time for removing the solvent can thus be determined automatically and the solvent can then be removed automatically without the need for a chemist or laboratory technician to be present. In this embodiment variant, the time for removing the solvent does not have to be preprogrammed, that is, estimated. In the following, the device according to the invention for substance analysis by means of thin layer chromatography is described in more detail with reference to the attached drawings using seven exemplary embodiments. Show it:

1 shows a sectional view of a first exemplary embodiment of the device according to the invention for substance analysis by means of thin-layer chromatography with two solvent channels;

Figure 2 is a top view of the solvent pan of the device of Figure 1;

Fig. 3 is a sectional view of the solvent pan along the line A-A in Fig. 2;

4 shows a sectional view of the solvent trough according to line B-B in FIG. 2 with wall plates mounted therein and thin-film plates arranged therein;

Figure 5 is a top plan view of the tub cover of the device of Figure 1;

Figure 6 is a side view of a wall plate of the device of Figure 1;

Fig. 7 - a perspective view of the inventive

Device with reagent matrix, reagent container and hollow needle; 8 shows a sectional view of a second exemplary embodiment of the device according to the invention for substance analysis by means of thin-layer chromatography with a single solvent channel;

9 shows a sectional view of a third exemplary embodiment of the device according to the invention for substance analysis by means of thin layer chromatography with two solvent channels;

10 shows a sectional view of a fourth exemplary embodiment of the device according to the invention for substance analysis by means of thin-layer chromatography with a solvent channel;

11 is a plan view of the solvent pan of the fourth embodiment;

12 shows a sectional view of a fifth exemplary embodiment of the device according to the invention

Mass analysis by thin layer chromatography with two solvent channels;

13 shows a plan view of the tub cover of a sixth exemplary embodiment of the device according to the invention for substance analysis by means of thin-layer chromatography with two solvent channels and

14 - a top view of the tub cover of a seventh embodiment of the - lo sen device for substance analysis by means of thin layer chromatography with two solvent channels.

First embodiment - Figures 1 to 7

The illustrated first exemplary embodiment of a device according to the invention for substance analysis by means of thin-layer chromatography comprises a solvent trough 1 in which two wall plates 4 and 5 are mounted vertically by means of four setscrews 40 and 50 arranged in thread counters 41, 42, 51 and 52. The solvent v / anne 1 has for receiving the wall plates 4, 5 grooves 15 into which the wall plates 4, 5 are inserted. In the central area, the wall plates 4, 5 each have a recess 41 into which the groove-free central area of the solvent trough 1 projects. The two wall plates 4, 5 are spaced apart from one another, so that an addition and removal tool, here a hollow needle 7, can be guided between them to solvent supply points 111 and 121.

The solvent front 1 has two separate solvent channels 11 and 12, each of which is divided into two halves by a separating nose 13 and 14, respectively, and in which the solvent supply points 111, 121 are arranged. The solvent channels 11, 12 are supplied with solvent via these solvent supply points 111, 121, wherein different solvents can be supplied to the two solvent channels 11, 12. In the present exemplary embodiment, they also serve as solvent suction points. So that the solvent can be extracted as completely as possible, the solvent Tel channels 11, 12 inclined on the one hand at an angle β to the longitudinal central axis of the solvent trough 1 and on the other hand also to the transverse central axis, so that the solvent is fed to the solvent and suction points 111, 121 flows to.

Normally, up to four thin-layer plates 2, 3 are placed obliquely in the solvent channels 11, 12, which are supported on the bottoms and on the sides 112, 122 of the solvent channels 11, 12 and on the wall plates 4, 5. The angle of inclination of the thin-layer plates 2, 3, i.e. the angle α between the thin-layer plates 2, 3 and the horizontal is about 55 ° in the present case, which is a simple drop or application from above of the substance to be analyzed and a suitable wetting with solvent and good upward migration of the solvent together with the substance or components to be analyzed.

Above the solvent trough 1 and the thin-layer plates 2, 3, a trough cover 6 is arranged, which provides a seal to the outside, so that saturated atmospheres can arise on both sides of the two wall plates 4, 5, which evaporate the solvent too quickly on the thin-layer plates Prevent 2, 3. Two longitudinal ribs 64, 65 of the tub cover 6 engage between the two wall plates 4, 5 and thus fix the tub cover 6 in the lateral direction. The tub cover 6 has holes 62 and 63, which allow the insertion of the hollow needle 7, an addition device for adding solvent to the solvent supply points 111, 121, and holes 61, which insert the hollow needle 7 for dropping or applying Allow substances to be analyzed on thin-layer plates 2, 3. The holes 61, 62, 63 are preferably closed with septa or a septa plate.

The solvent trough 1 with the thin-layer plates 2, 3 and the trough cover 6 can, for example, as shown in FIG. 7, be arranged in a frame 80 under a reagent matrix 8 which includes receiving holes 81 for reagent containers 9 and through-holes 82 between them. through which the hollow needle 7 for adding and removing substances and solvents to be analyzed can be guided.

A commercially available robot which can be moved in one or two horizontal and vertical directions can be used as the feed device for guiding the hollow needle 7.

Second embodiment - Figure 8

In this second exemplary embodiment, a device according to the invention has, in addition to a tub cover 206, a solvent tub 201 with only one solvent channel 212, only one wall plate 205 fastened with grub screws 250 and normally only two thin-layer plates 203. Otherwise, what has been said about the first embodiment applies accordingly.

Third embodiment - Figure 9

In this third exemplary embodiment, a tub cover 306 and a solvent tub 301 are formed in this way and two wall plates 304, 305 are formed in pins 340, 350 in the solvent tank 301 so that the normally four thin-layer plates 302, 303 are parallel to one another. Otherwise, what has been said about the first embodiment applies accordingly.

Fourth embodiment - Figures 10 and 11

In this fourth exemplary embodiment, in addition to a tub cover 406, a device according to the invention has a solvent tub 401 with a solvent channel 412, a wall plate 405 fastened with grub screws 450 and normally two thin-layer plates 403. A solvent supply and suction point 421 is arranged here in front of instead of behind the wall plate 405. Otherwise, what has been said about the first embodiment applies accordingly.

Fifth embodiment - Figure 12

In this fifth exemplary embodiment, a device according to the invention has a tub cover 506 with side walls which run approximately parallel to the thin-layer plates. Otherwise, what has been said about the first embodiment applies accordingly.

Sixth embodiment - Figure 13

In this sixth exemplary embodiment, a tub cover 606 has three slots 661, 662 instead of holes for the addition and removal tool, which are preferably closed with septa or septa plates. Otherwise, what has been said about the first embodiment applies accordingly. Seventh embodiment - FIG. 14

In this seventh exemplary embodiment, a tub cover 706 has an open area 761 instead of holes for the addition and removal tool, which is preferably closed with a septa plate. Otherwise, what has been said about the first embodiment applies accordingly.

Claims

claims

1. Device for substance analysis by means of thin layer chromatography, with a solvent tank (1, 201; 301; 401), which has at least one solvent channel (11, 12; 212; 311, 312; 412), characterized in that it has means (4, 5 ; 205; 304, 305; 405), which make it possible to arrange a thin-layer plate (2, 3; 203; 302, 303; 403) standing obliquely to the horizontal in the solvent channel, so that the substance to be analyzed can be dripped onto the thin-layer plate from above or can be applied and the solvent channel can be supplied at a solvent supply point (111, 121; 421) so that the migration of components of the substance to be analyzed can be started without changing the position of the thin-layer plate got to.

2. Device according to claim 1, characterized in that the solvent channel solvent can be supplied from above.

3. Device according to claim 1 or 2, characterized in that the means which make it possible to arrange a thin-layer plate standing obliquely to the horizontal in the solvent channel are designed such that the angle α zv / ischen of an arranged thin-layer plate and the horizontal between 1 ° and 89 °, preferably between 5 ° and 85 °.

4. The device according to claim 3, characterized in that the means which make it possible to arrange a thin-layer plate standing obliquely to the horizontal in the solvent channel are designed such that the angle α is between 20 ° and 80 °, preferably between 40 ° and 50 ° is.

5. Device according to one of claims 1 to 4, characterized in that the solvent tank has two or more independent solvent channels, wherein at least two thin-layer plates can preferably be arranged in a solvent channel.

6. Device according to one of claims 1 to 5, characterized in that it has a solvent suction point, which preferably corresponds to the solvent supply point.

7. The device according to claim 6, characterized in that the or each solvent channel is inclined towards a solvent suction point.

8. Device according to one of claims 1 to 7, characterized in that it has a tub cover (6; 206; 306, 406; 506; 606; 706), which largely the solvent channel or the solvent channels and the thin-film plate or plates locks against the outside.

9. Device according to claims 5 and 8, characterized in that the space between the solvent tank and the tub cover is divided by a between the partition between the two solvent channels, which preferably comprises two wall plates (4, 5; 205; 304, 305; 405), which preferably serve simultaneously as support plates for thin-layer plates.

10. The device according to claim 8 or 9, characterized in that the tub cover has holes (61, 62, 63) or slots (661, 662) or an open surface (761) at the top, which the supply of solvent and dripping or allow the application of substances to be analyzed to the thin-layer plate or plates through the trough cover, the holes, slots or the open area preferably being closed with septa or a septa plate.

11. Device according to one of claims 1 to 10, characterized in that it comprises an addition device (7) with which substances to be analyzed can be automatically dripped or applied onto the thin-layer plate or plates.

12. The device according to one of the claims 1 to 11, characterized in that it comprises an addition device (7) with which solvents can be automatically supplied at the solvent supply point (s).

13. Device according to one of claims 6 to 12, characterized in that it comprises an addition device (7) with which solvents can be automatically sucked off from above at the or the solvent suction points.

14. Device according to one of claims 11 to 13, characterized in that the feed device comprises a hollow needle (7) which can be moved vertically and in at least one horizontal direction.

15. Device according to one of claims 1 to 14, characterized in that it has a reagent matrix (8), the receiving holes (81) for reagent containers

(9) and between them continuous through holes (82), through which an addition and removal tool (7) for adding and removing substances and solvents to be analyzed can be passed.

16. Device according to one of claims 1 to 15, characterized in that it comprises means for visualizing components of the substance to be analyzed which have migrated upwards, which preferably comprise a UV lamp and / or means for spraying with chemical reagents.

17. Device according to one of claims 1 to 16, characterized in that it has means for determining the time at which existing solvent is to be removed from the solvent channel or channels, which preferably comprise a CCD camera.