DE3118665A1 - DEVICE FOR LINEAR OVERPRESSURE LAYER CHROMATOGRAPHY - Google Patents

Description

en
acM 40 2S

Müszeripari Müvek LABORATORY

2501. Esztergom, Rudas Laszlo and 44. HUNGARY

Device for linear upper pressure layer chromatography

The invention relates to an apparatus for linear overpressure layer chromatography; the device has a base plate carrying the sorbent layer. With the device can one that is pneumatically, hydraulically or otherwise pressurized by means of an elastic plate, closed Sorbent layer at adjustable temperature over any length and width in one or two directions, dry or wet. isocratic or gradient, in one or in two dimensions and also in the so-called upper course technique be chroraatographed.

The upper pressure layer chromatography is a liquid chromatographic technique on closed, flat surfaces · The sorbent layer is under pressure from the outside standing plate completely closed, and between the partial

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Chen des sorbent, the solvent is kept in a forced flow with the help of a suitable metering device (Hungarian patent specification No. 173 749) This latest form of liquid chromatography on surfaces has several advantages compared to classic layer chromatography: the running time is shorter, the resolution better, it becomes less solvent required; the development carried out with viscous solvent mixtures can be accelerated, the process can be followed visually, the use of aggressive reagents is possible, etc. In addition, upper pressure layer chromatography has all the advantages of high pressure column chromatography.

For upper pressure layer chromatography only the circular upper pressure chamber is known (E. Tyihok, E. Mincsovics and H · Kaläsz: 0. Chromatogr · 174, 75/1979 /). On one, the lower plate of the device made of Plexiglas, there is the commercially available or painted sorbent layer of maximum dimensions of 200x200 mm. The cover plate made of Plexiglas rests on this, in which the following components are built: a) a manometer, b) a pressurized sample dosing device, c) a gas inlet opening, d) an O-ring to enclose the plastic film, e) a plastic membrane, f) the opening for introducing the solvent, provided with elastic, spiral metal lines. The Oeckplatte is attached accordingly and the cushion is inflated with nitrogen, for example.

For all previously known variations of layer chromatography is characteristic that the distance covered by the solvent (z in cm) and the required distance Time (t in see) via an equation of the 2nd degree

related to each other, before k is the rate constant 1st. This applies to both the round disc variant and the linear variant of the so-called HPTLC technology (R.E. Kaiser:

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Introduction to high-performance thin-layer chromatography, Institute for Chromatography, Bad DOrkheim, 1976) as well as overpressure layer chromatography for the circular disk device (Tyihak et al .: 0. Chromatogr. 174 , 75/1979 /); in the latter case, it is not possible to maintain a constant solvent velocity along the circle radius for reasons of principle alone.

In the linear variant of overpressure layer chromatography, the prerequisite for a good layer chromatogram, namely the constant flow rate of the solvent or the linear solvent front, can only be achieved by using layers closed at the edges and introducing the solvent by means of a wire or plate placed in front of the point of entry of the solvent or through a groove cut into the sorbent layer (Hungarian patent application dated December 6, 1979, note: Chinoin Rt.).

In the case of linear upper pressure layer chromatography, there is accordingly between that which is covered by the solvent Distance (z in cm) and the required time (t in see) a linear relationship:

f ■ "

where k is the rate constant, ie the upper pressure layer chromatography offers ratios like the columns «. Chromatography, which means a qualitatively new chromatographic technique. Of the two possible variants of overpressure layer chromatography, namely the circular and the linear, the development of the latter is paramount, since technical progress towards more effective separation can be expected there.

For linear overpressure layer chromatography, special sorbent plates are required (according to the above patent application) as well as a device (a.

The advanced device according to the Hungarian patent specification No. 173 749 is, according to the report on it to judge (Tyihak et al .: O. Chromatogr. 191, 293 / 1980 /), only suitable for chromatography over relatively short distances, although from the above context First degree it can be seen that the flow rate of the solvent also in further distance remains constant. Well, as is well known,. the theoretical number of trays or that of Kaiser / Kaiser (Editor) in the book "Introduction to High-Performance Thin-Layer Chromatography" (institute for Chromatography, Bad Dürkheim, 1976) introduced proportional separation number the running distance increases, over longer distances (for example 30-100 cm) an all previous one could be surpassed Separation can be achieved.

It follows from the basic principle of overpressure layer chromatography, that - as with the column chromatography with solid filling - with the exclusion of the vapors the solvent is worked. This leads mainly in liquid-solid chromatography (adsorption chromatography) with the frequently used multi-component solvents to a segregation of the solvents, which in some cases unsatisfactory separation, an accumulation of each other results in substances to be separated at the zone boundary. In high-performance column chromatography, in such Precondition the sorbent with the solvent a linear device suitable for this procedure is not currently known. The development of one too linear device suitable for wet processes is also desirable because it enables the processes in high-performance Column chromatography is modeled and both techniques are used simultaneously for analytical and / or preparative purposes can be.

The aim of the invention is to eliminate the deficiency described and to provide a device for linear

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Overpressure layer chromatography, with the sealed sorbent layer, pneumatically, hydraulically or otherwise pressurized by means of an elastic plate, at an adjustable temperature over any length and width in one or two directions, dry or wet, isocratic or gradient, in one or may be chromatographed in two dimensions and also in so-called r d. upper reaches art.

The invention is based on the technically sound knowledge that in linear upper pressure layer chromatography the flow rate of the solvent is constant over the entire length of the layer, which gives the opportunity to develop over longer distances and thus a better separation.

The invention is also based on the knowledge that the disadvantageous consequences of solvent segregation are similar as in high-performance column chromatography by preconditioning with solvent, can be eliminated by applying the sample under pressure if necessary This is also the prerequisite for modeling the separation processes in high-performance column chromatography. Ed also realized that one or two directions can be chromatographed if one Used sorbent layers, which are only closed on the corresponding sides, and the chromatography device has a system of openings which can be used as required for introducing the solvent. Finally it was recognized that by adjusting the temperature of the sorbent layer to one deviating from the normal up or down Value the sharpness of the separation can be improved.

The invention therefore relates to an apparatus for linear upper pressure layer chromatography, which one the Has a base plate carrying the sorbent layer. When building the device according to the invention, the theoretically proven

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linear relationship between the theoretical number of trays (separation number) and that covered by the solvent Distance exploited by creating a device that is also suitable for long distances. For the wet process is the device with one for variable solvent supply equipped with a suitable dosing system · By installing a The temperature controller enables the temperature of the sorbent layer and thus the working temperature to regulate.

The device according to the invention contains the following components:

1. a base plate corresponding to the claims of the new method for receiving the sorbent layer and to regulate the temperature

2. An elastic, cushioned, chemically resistant, suitable for pressing the sorbent layer transparent pressure plate.

3. Capillary connection for introducing the eluent and samples.

The invention is explained closer to H _a nd of embodiments with reference to the drawings *

Fig. 1 shows the section through an embodiment of the device according to the invention, in

Fig. 2 shows the section through the capillary connections for introducing the eluent, the

Figs. 2a, b, c and d show further embodiments of the capillary connections in section and in plan view,

Fig. 3 shows the device for the sample task, the

Fig. 4a, b, c and d illustrate different possibilities to apply the sample and the eluant.

As can be seen from FIG. 1, the sorbent layer is supported by a base plate 2 which can be thermostatically controlled. the Base plate 2 can be connected to an ultra-thermostat via nozzle 3. The membrane 4 de * - the sorbent layer pressing plate is attached to a transparent plastic

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or glass plate 5 attached «close to the membrane Capillary nozzles 6 and 7 for introducing the sample and the eluant. The capillary stubs lead through the transparent plate through seals 8 to the outside.

The base plate 2 und.die pressure plate 5 are through a patent lock 9 pressed against each other. To introduce of the pressurized medium 10 (liquid or gas) a valve 11 is used. The pressure conditions are displayed by a manometer 12. That on one The elastic cushion formed on the side of the pressure plate 5 closes off the sorbent layer 1 directly. The pressure force depends on the level of the resulting pressure.

The seals β of the capillary nozzles enable the membrane 4 or the capillary nozzles to move 6 and 7 so that the seal of the pressurized space 10 is ensured.

As can be seen from FIG. 2, the capillary nozzle 6 used for introducing the Eluler means closes over a cone on the membrane 4 en. The tightness is achieved by a conical base 14 and a thread emitter 14

The eluent can be introduced through a channel 15 running in the sorbent layer, but it is also possible to place a spacer on the sorbent layer t in this case the liquid enters the sorbent through the channel 18 between the dietary piece 17 and the membrane 4 .

First, the channel 15 or the channel 18 fills, and by increasing the pressure, the linear flow in the direction indicated by Pfoilo begins in the sorbent layer 1, which is closed off on the side by impregnations 19.

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The capillary connection 7 shown in FIG. 3 for introduction the sample lies directly on the sorbent layer 1. The sample introduced by means of overpressure flows into the sorbent. Oils sample can be placed in the dry sorbent layer or in the sorbent layer previously wetted with eluent be introduced. The upper pressure when feeding in the sample depends on the size of the pressure in the pressure chamber 10, the size of the sorbent particles and the viscosity ratios.

In Fig. 4a. b, c and d are different variants the sample application and eluent supply.

a) one-way chromatography; that entering from the capillary connection 6 through the channel 15 into the sorbent Eluant moves the components of the previously applied samples 20 linearly in one direction (Fig. 4a),

b) Two-way chromatography. That coming from the capillary connection 6 through the channel 15 into the sorbent Eluent transports the components of the samples 20 applied in large numbers linearly in two Directions (Flg. 4b),

c) One-way chromatography, sample application negative pressure; the eluent entering through the capillary connection 6 and the channel 15 is moistened or respectively washes through the sorbent layer. The sample is introduced through the capillary connection 7. The flow of the eluent transports the sample linearly in one direction (Fig. 4c),

d) chromatography in two directions, sample application under pressure; that entering through the capillary connection 6 The eluent wets the sorbent in two directions. The samples pass through the two rows Capillary connections 7 in the sorbent layer. The flow of the eluent transports the samples linearly in two Directions.

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The front of the eluent can be seen through the transparent AndrQckplatte can be followed visually through. The movement of the eluted components can in the case of colored Connections immediately, in the case of colorless connections can be observed with the help of labeled dyes

The chromatogram is evaluated on the usual for layer chromatograms

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Claims (1)

Patent Attorneys -:;:. - - «. Dipl.-Ing. R. Lemcke: .. ^{"\. ■"::} oiioerr Dr.-Ing. H.-J. Brommer '"" "J M O b Q O 75 Karlsruhe 1 _ Amalienstraüe 28
P.O. Box 40 26 Patent application Device for linear overpressure üchiclitchroinotogrophie, which has a sorbent layer troyendo basic plot,
characterized in that it has an on the base plate (2) fixable, with oinor dio üorbonoochioht (l) from obon elastic abechludendor membrane (4) voraohono cover plate (5), a between the mombron (4) and the cover plate (s)
a pressure medium introducing valve (11) and, sealed through the cover plate (b) and passed through the mombrnn (4), at least one inlet organ (θ) for the eluent emittol
and at least one probation task (7). 130065/0872