EP1119767A1

EP1119767A1 - Method and device for the rapid liquid chromatographic separation of substance mixtures and for the identification of substances

Info

Publication number: EP1119767A1
Application number: EP99952538A
Authority: EP
Inventors: Lutz MÜLLER-KUHRT; Holger Gumm; Holger Notzke; Ralf; God
Original assignee: Sepiatec GmbH
Current assignee: Sepiatec GmbH
Priority date: 1998-10-08
Filing date: 1999-10-08
Publication date: 2001-08-01
Also published as: DE19847439C2; DE19847439A1; CA2346358A1; WO2000022429A1; AU6469599A; JP2002527748A

Abstract

The invention relates to a method and device for the rapid liquid chromatographic separation of substance mixtures and for the identification of substances. The aim of the invention is to provide a device and a method for the liquid chromatographic separation, isolation, and identification of substances in analytic and semipreparative areas, with which a test for determining the activity of substance mixtures is dispensed with. In addition, the inventive method and device carry out the separation of substance mixtures, and the isolation and identification of the individual substances more quickly than prior art methods and devices. To these ends, a method and device are used with which substance mixtures, in a software-controlled rapid liquid chromatographic two-step separation, are subjected to a preliminary separation in a first step and, in the second step, the fractions which were subjected to the preliminary separation and which are deposited in collection columns are parallelly separated into at least two separation lines in a fine manner. The finely separated fractions are parallelly identified and parallelly isolated.

Description

Method and device for the rapid liquid chromatographic separation of substance mixtures and identification of substances

description

The invention relates to a method and a device for the rapid liquid chromatographic separation of substance mixtures and identification of substances according to the preambles of claims 1 and 5.

For example, the problem in pharmaceutical research is to isolate pharmaceutically active substances from substance mixtures. Natural product extracts or mixtures of substances generated by combinatorial chemistry are tested for their potential effectiveness. From substance mixtures that have shown effectiveness, an attempt is then made to isolate the active substances using complex separation processes. The individual substances of the mixture isolated in this way are then subjected to a new activity test. The structure of the effective individual substances now found is examined in order to rule out possibly already known active substances. A disadvantage of this method is that the effectiveness of individual substances can be suppressed in the test of the substance mixtures by means of superimposition effects and these remain undetected. Another disadvantage is that overlay effects can pretend to be effective and then it is searched in vain for these supposed active substances in the substance mixture in vain. Finally, disadvantageously, known substances are only excluded after carrying out at least two tests for biological effectiveness and after elaborate isolation processes, which is very expensive. As a rule, large amounts of substance are required to carry out these tests, ie separations have to be carried out on a preparative scale. In terms of investment costs, however, preparative plants are more expensive than analytical plants. Preparative systems for the separation also consume considerably more solvents and buffer substances, which makes their operation expensive and also causes greater disposal problems and environmental pollution.

The invention is based on the object of offering a device and a method for liquid-chromatographic separation, isolation and identification of substances in the analytical and semi-preparative field, with which a test for the effect of substance mixtures is unnecessary and it is possible to separate substance mixtures faster than previously, isolate and identify the individual substances.

The problem is solved with the characterizing parts of claims 1 and 5.

Advantageous further developments are specified in the subclaims. The invention has several advantages. The substances no longer have to be tested twice, namely beforehand in the mixture of substances and after isolation. According to the invention, the time-consuming and costly first test of the substance mixtures, which is sometimes flawed, can be omitted. Instead, after the combined isolation and identification, only potentially new active substances are subjected to further tests. The previously costly processing of known substances is no longer necessary. The time and cost involved in determining a new active substance can be significantly reduced. In addition, this procedure is safer because the test results on unknown individual substances are clear and all active substances present in the mixture are also recorded.

The substance mixtures to be investigated are processed in a two-stage separation. In the second chromatographic separation stage, several fractions from the first separation step can be separated in parallel by the inventive connection of separation columns and solid-phase extraction columns (collecting columns) with the pump unit. Thus, this device works much faster and therefore cheaper than known two-stage devices.

The individual substances are identified by known direct computer-controlled comparison of the chromatograms and spectra obtained from detectors and the retention area from the first separation step and the Retention time from the second separation step with information about known substances in a database. Ultraviolet absorption, mass spectrometry, light scattering, fluorescence, infrared spectroscopy and nuclear magnetic resonance spectroscopy are possible as detection and identification principles. The inclusion of further identification parameters such as B. Source and origin of the sample is possible. Since fewer tests are necessary to identify the substances in the mixture and to exclude substances that are already known, this system can be dimensioned on an analytical and semi-preparative scale. Analytical and semi-preparative systems are much cheaper to purchase and operate than the previously used preparative systems. Due to the lower consumption of solvents and buffer substances, the method and the device according to the invention are environmentally friendly due to the lower amounts of waste.

The invention is explained in more detail with reference to a drawing and an embodiment.

Show it

1 is a schematic representation of the process of equilibration in the first separation step and rinsing the feed column battery,

2 shows a schematic illustration of the separation of a substance mixture in the first separation step and adsorption of fractions on the first collecting column battery, 3 shows a schematic illustration of the separation of a substance mixture in the first separation step and adsorption of fractions on the second collecting column battery,

4 shows a schematic representation of the separation of a substance mixture in the first separation step and adsorption of fractions on the third collecting column battery,

5 shows a schematic representation of the equilibration of the separation column batteries of the second separation step,

Fig. 6 is a schematic representation of a parallel separation of absorbed fractions in the second separation step and

7 shows a schematic illustration of the equilibration of a collecting column battery.

1 to 7 show an example of the structure and flow diagram of a device according to the invention with a separation column and three subordinate separation lines.

A pump unit 2, which consists of three pumps 2.1 to 2.3, is via the 6-way 2-position valves 3.1 and 3.3 and the 3-way 2-position valve 5.7 with a charging column battery 6, a separation column 10, for the first separation stage and a second separation stage, which consists of three separation lines that can be operated in parallel, each of which is preceded by a 6-way, 2-position valve 3.5, 3.6 and 3.7, connected. This makes it possible to transport the mobile phase in any desired composition one after the other and in parallel into all areas of the device.

Each dividing line has a collecting column battery 7, 8 and 9 and a separating column battery 11, 12 and 13. As an example, the collecting column battery 7 contains the collecting columns 7.1 to 7.6 and the separating column battery 11 contains the separating columns 11.1 and 11.2. The two other dividing lines shown are constructed identically. Other variants with more feed columns 6.1 to 6.6 of the feed column battery 6, a plurality of separation columns 10, more than three collecting column batteries 7, 8 and 9, each with more than six collecting columns and more than three separation column batteries 11, 12 and 13 with more than six separation columns per battery are possible .

The sequence of the method according to the invention is described below by way of example. Mixed substance samples are each dissolved in a solvent and an adsorbent is added. The solvent is then removed using a rotary evaporator so that the adsorbents covered with sample material achieve free-flowing properties. The adsorbents coated with the substance mixture are filled into the charging columns 6.1 to 6.6 of the charging column battery 6 and installed in the charging column battery 6. The following program steps are controlled by software.

1, the separation column 10 is equilibrated. In parallel, the air from the Feeder battery 6 removed. Via the pump 2.3, the 3-way 2-position valve 5.7 and the 6-way 2-position valves 3.1 and 3.3, the air is removed from one of the dry-filled feed columns 6.1 to 6.6 with water, the next to be injected. At the same time, the separation column 10 is equilibrated with a suitable solvent by means of the pump 2.1, the 6-way 2-position valves 3.1 and 3.3.

2 shows the separation of the substance mixture in the first separation stage on the separation column 10 and the subsequent adsorption of the fractions in a separation line with the collection columns 7.1 to 7.6 of the collection column battery 7.

If the air is removed from one of the feed columns 6.1 to 6.6, the separation program is started. First the 6-way 2-position valves 3.3 and 3.5 are switched. The components of the mobile phase can be entered into the system by means of the pump unit 2 via a low pressure valve unit 1 with the low pressure valves 1.1 to 1.3. The mobile phase is transported via the low-pressure valve 1.1 of the pump 2.1 and the pump 2.1, whereby this system can be operated both isocratically and with a gradient. Via the 6-way 2-position valve 3.3 and the 7-way 6-position valves 4.1 / 4.2, the mobile phase of pump 2.1 is guided to the feed column 6.1 to 6.6 from which sample material is to be processed. The sample to be separated is transferred from one of the feed columns 6.1 to 6.6 to the separation column 10. Those emerging from the separation column 10 Separate test components pass through a 6-way 2-position valve 3.4 and the detector 14.1 to a T-piece 17, where water is mixed into the mobile phase via the pump 2.2 and the 6-way 2-position valve 3.1. The amount of water mixed depends on the polarity of the substances to be separated. The polarity of the mobile phase, which is increased by water, now enables adsorption on the collecting columns 7.1 to 7.6 of the collecting column battery 7. Via the 6-way, 2-position valve 3.5, adsorption onto the collecting column battery 7 is first carried out. The collecting columns 7.1 to 7.6 are covered with fractions one after the other.

3 shows the adsorption of further fractions on the collecting columns 8.1 to 8.6 of the collecting column battery 8. When all the collecting columns of the collecting column battery 7 are occupied with fractions, the 6-way 2-position valves 3.5 and 3.6 switch the collecting column battery 8 into the eluent stream. Now the collecting columns 8.1 to 8.6 are covered with fractions one after the other.

4 shows the adsorption of fractions on the collecting columns 9.1 to 9.6 of the collecting column battery 9. When all the collecting columns 8.1 to 8.6 of the collecting column battery 8 are occupied with fractions, the 6-way 2-position valves 3.6 and 3.7 switch the collecting column battery 9 into the eluent stream. Now the collecting columns 9.1 to 9.6 are covered with fractions one after the other. In the following process step, the fractions adsorbed on the three collecting column batteries 7, 8 and 9 become parallel eluted and further separated on correspondingly assigned separating column batteries 11, 12 and 13.

Before each separation, the separation column batteries 11, 12 and 13 are equilibrated. 5 shows the equilibration of the separating column batteries 11, 12 and 13. For the equilibration, the mobile phase is led via the pump 2.1, the 6-way 2-position valve 3.1 and 3.5 to the separation columns 11.1 and 11.2 of the separation column battery 11. From there, the mobile phase is led into the waste via the 6-way 2-position valve 3.4, the detector 14.1 and a fraction collector 15.1. At the same time, the separation columns 12.1 and 12.2 of the separation column battery are equilibrated via the pump 2.2, the 6-way 2-position valves 3.1 and 3.6 as well as a detector 14.2 and fraction collector 15.2. Likewise, the separation columns 13.1 and 13.2 are equilibrated in parallel via the pump 2.3, the 6-way 2-position valve 3.7 and the 3-way 2-position valve 5.7 as well as a detector 14.3 and a fraction collector 15.3.

6 shows the parallel separation of the fractions adsorbed on the collecting column batteries 7, 8 and 9 on the separating column batteries 11, 12 and 13. In order to initiate the separation step, the mobile phase is guided to the collecting column battery 7 via the pump 2.1 of the pump unit 2 and the 6-way 2-position valves 3.1 and 3.5. The first eluted fraction from the collecting column battery 7 (e.g. from collecting column 7.1) is conducted via the 6-way 2-position valve 3.5 to the separating column battery 11. There you can choose a software-controlled one the separation columns 11.1 or 11.2 are switched on. The separated components are then led to the detector 14.1 via the 6-way 2-position valves 3.5 and 3.4. The software in the electronic control unit evaluates the signals with the aid of peak detection and directs the separated components into the corresponding vials of the fraction collector 15.1. At the same time, time control of the fraction collector 15.1 is also possible. This timing can be activated automatically if no peak passes the detector.

At the same time, the mobile phase is conveyed to the collecting column battery 8 via the pump 2.2 and the 6-way 2-position valves 3.1 and 3.6. The first eluted fraction from the collecting column battery 8 (e.g. from the collecting column 8.1) is conducted to the separating column battery 12 via the 6-way, 2-position valve 3.6. There, one of the separating columns 12.1 or 12.2 can be switched on under software control. The separated components are led to the detector 14.2. Here, too, the software evaluates the signals with the help of peak detection and then directs the separated components into the corresponding vials of the fraction collector 15.2. This fraction collector 15.2 can also be time-controlled. This timing can be activated automatically if no peak passes the detector.

Parallel to the processes in two dividing lines, the third dividing line is activated with regard to the initiation of the separating step. For this purpose, the mobile phase via pump 2.3 as well as the 3-way 2-position valve 5.7 and the 6-way 2-position valve 3.7 are used Collecting column battery 9 promoted. The first eluted fraction from the collecting column battery 9 (e.g. from the collecting column 9.1) is led to the separating column battery 13 via the valve 3.7. There, one of the separation columns 13.1 or 13.2 can be switched on using software control. The separated components are led to the detector 14.3. The subsequent fraction collector 15.3 is controlled as already described. After the respective first fractions have been processed in parallel, the separation column batteries 11, 12 and 13 are again equilibrated to prepare and separate the next fractions (cf. FIG. 5). Then the 7-way 6-position valves 4.3 / 4.4, 4.5 / 4.6 and 4.7 / 4.8 on the collecting column batteries 7, 8 and 9 switch on, so that the second fractions can now be processed, as shown in FIG. 6. These processes continue until all fractions have been processed.

7 shows the equilibration of the collecting columns 7.1 to 7.6 of the collecting column battery 7. In this program sequence step, the collecting columns 7.1 to 7.6 are rinsed with water and thus prepared for the next run. This is done sequentially via the pump 2.2, the 6-way 2-position valves 3.1, 3.5, 3.6, 3.7 and the 7-way 6-position valves 4.3 / 4.4 of the collecting column battery 7. The equilibration of the collecting column batteries 8 and 9 is done analogously. The 6-way 2-position valves 3.5 and 3.6 are switched and the 6-way 2-position valves 3.1, 3.5, 3.6, 3.7 and the 7-way 6-position valves 4.5 / 4.6 of the pump 2.2 Catchment Column battery 8, the collecting columns 8.1 to 8.6 are equilibrated. Then the 6-way 2-position valves 3.6 and 3.7 are switched and via pump 2.2 the 6-way 2-position valves 3.1, 3.5, 3.6, 3.7 and the 7-way 6-position valves 4.7 / 4.8 the collecting column battery 9, the collecting columns 9.1 to 9.6 are equilibrated. After this program sequence, the 7-way 6-position valves 4.1 / 4.2 of the charging battery 6 are switched to the next charging column (e.g. 6.2) and the entire program sequence starts again.

(Sequence step 1: equilibrate the separation column 10 and

Vent the feed column 6.2, shown in Fig. 1, etc.)

After processing this second sample, the following feed column 6.3 can be switched into the eluent stream. Since already completed sample columns can be replaced with new ones at any time, continuous operation with an unlimited number of samples is possible.

During the first and second separation steps, chromatograms, retention data and spectra are collected via detectors 14.1, 14.2 and 14.3, processed directly in a computer and compared with the data of known substances. In this way, substances already known online can be identified and sorted out. In case of doubt, additional data that is obtained offline after separation and isolation can be used for identification. Reference list

1 low pressure valve unit

1.1 low pressure valve

1.2 low pressure valve

1.3 Low pressure valve 2 pump unit

2.1 pump

2.2 pump

2.3 pump

3 6-way 2-position valve 3.1 6-way 2-position valve

3.3 6-way 2-position valve

3.4 6-way 2-position valve

3.5 6-way 2-position valve

3.6 6-way 2-position valve 3.7 6-way 2-position valve

4 7-way 6-position valve

4.1 7-way 6-position valve

4.2 7-way 6-position valve

4.3 7-way 6-position valve 4.4 7-way 6-position valve

4.5 7-way 6-position valve

4.6 7-way 6-position valve

4.7 7-way 6-position valve

4.8 7-way 6-position valve 5 3-way 2-position valve

5.1 3-way 2-position valve

5.2 3-way 2-position valve

5.3 3-way 2-position valve 5.4 3-way 2-position valve

5.5 3-way 2-position valve

5.6 3-way 2-position valve

5.7 3-way 2-position valve

6 Feeder battery 5.1 Feeder column

5.2 Feed column

5.3 Feed column

5.4 Feed column

5.5 Feed column 5.6 Feed column

7 collecting column battery

7.1 Collecting column

7.2 Collecting column

7.3 Collecting column 7.4 Collecting column

7.5 Collecting column

7.6 Collecting column

8 Collection column battery 8.1 Collection column 8.2 Collection column

8.3 Collecting column

8.4 Collecting column

8.5 collecting column

8.6 Collecting column 9 collecting column battery

9.1 Collecting columns

9.2 Collecting columns

9.3 Collecting columns 9.4 Collecting columns 9.5 collecting columns

9.6 Collecting columns

10 separation column

11 Separation column battery 11.1 Separation column

11.2 Separation column

12 column battery

12.1 separation column

12.2 Separation column 13 separation column battery

13.1 separation column

13.2 Separation column

14 detectors 14.1 detector 14.2 detector

14.3 detector

15 fraction collectors

15.1 Fraction collectors

15.2 Fraction Collector 15.3 Fraction Collector

16 waste

16.1 Waste

16.2 Waste

17 T-piece

Claims

Patent claims

1. Process for the rapid liquid chromatographic separation and identification of substances, characterized in that substance mixtures are pre-separated in a software-controlled rapid liquid chromatographic two-stage separation in the first stage and in the second stage the pre-separated fractions deposited in collecting columns are finely separated in parallel in at least two dividing lines, the finely separated ones Fractions are identified in parallel and isolated in parallel.

2. The method according to claim 1, characterized in that in the first separation stage the pre-separation of substance mixtures takes place one after the other and in the second stage the fine separation takes place one after the other and/or in parallel.

3. Method according to one of claims 1 or 2, characterized in that at least one detector (14.1) after both the first separation stage and after the second

Separation stage is used.

4. The method according to any one of claims 1 to 3, characterized in that the substances separated and isolated in the dividing lines are subjected to a further cleaning procedure, in particular an adsorptive cleaning.

5. Device for the rapid liquid chromatic separation and identification of substances consisting of several separation and collection columns as well as detector and feeding systems

Fraction collector, the interaction of which can be controlled via a central control unit, characterized in that at least one separation column (10) has several parallel liquid chromatographic separation lines, each consisting of a combination of separation column batteries (11, 12, 13) with collecting column batteries (7, 8, 9), Detector units (14) and fractionation collector units (15), arranged downstream, are a pump unit (2) consisting of three pumps (2.1,

2.2, 2.3) to promote the mobile phase is functionally connected to both the separation column (10) and the separation lines and that software-switchable multi-way valves are arranged between the individual functional units.

6. Device according to claim 5, characterized in that in front of each dividing line there is a multi-way valve (3.5,

3.6, 3.7) is arranged.

7. Device according to claim 5 or 6, characterized in that further collecting columns are arranged downstream of the dividing lines.