WO2012122980A1

WO2012122980A1 - Solvent storage system for hplc systems with low flow rates

Info

Publication number: WO2012122980A1
Application number: PCT/DE2012/100066
Authority: WO
Inventors: Gervin Ruegenberg
Original assignee: Dionex Softron Gmbh
Priority date: 2011-03-15
Filing date: 2012-03-14
Publication date: 2012-09-20
Also published as: DE102011001270A1

Abstract

The invention relates to a method for supplying HPLC systems with at least one solvent (100, 100a, 100b), in which the solvent (100, 100a, 100b) is discharged from at least one storage container (1, 1a, 1b) that is closed off in a gas-tight manner, wherein the container volume decreases to the same extent as the solvent (100, 100a, 100b) leaves the container. The invention furthermore relates to an apparatus for carrying out this method, and to the use of a glass syringe (1, 1a, 1b) herefor.

Description

Solvent supply system for low flow rate HPLC systems

The invention relates to a supply method and a storage system for systems in high performance liquid chromatography (HPLC). In HPLC, solvents are pressurized by a pump and fed to a separation column over the length of which the pressure is reduced. Frequently, different solvents are mixed in the pump in order to vary the solvent composition (gradient operation).

A known difficulty in HPLC is that a certain amount of gases is usually dissolved in the solvents used. These gases can originate from the manufacturing or processing process of the solvents or from the ambient air. During prolonged storage in conventional solvent bottles, for example, a diffusion equilibrium arises between the dissolved gases and the air located above the liquid level. This balance depends on the type of solvent, the temperature, the air pressure and the amount of air present.

The dissolved gas has the following undesirable adverse effects:

Dissolved gases increase the UV absorption of the liquid. This is noticeable in the usual use of UV absorption detectors in HPLC systems as increased noise.

When the pressure is reduced (for example, by the suction vacuum of the pump), dissolved gases may again become gaseous and form bubbles which interfere with the operation of the pump.

At a higher temperature, as occurs, for example, in the chromatography column usually (due to frictional heat and optionally external heating), dissolved gas can become gaseous again at normal ambient pressure and form bubbles. This leads to disturbances in practically all customary detection methods, eg interference peaks in the optical detector or spray instabilities in the mass spectrometer.

These problems are exacerbated when aqueous and organic solvents are mixed. In such mixtures, the solubility of gases is usually considerably lower than in the pure solvents. After mixing, the solvent is then supersaturated with gas, which extremely aggravates the tendency to blister. As long as the mixed solvent is under high pressure, the gas is still kept in solution, but as the pressure nears ambient pressure, bubbles are created.

Another problem in HPLC is that the solvents are premixed or added to additives in many applications prior to use. Since the individual components of such solvent mixtures have different high partial pressures, they evaporate at different rates (selective evaporation), so that the mixing ratio changes over time. This deteriorates the chromatographic reproducibility, which is an essential quality criterion in HPLC. This is all the more problematic the less often the solvents are recirculated. In order to degas liquids, ie to reduce the amount of dissolved gas in the liquids, various known possibilities exist.

In the HPLC is widespread online vacuum degassing. In this case, the solvent to be degassed passes through a vacuum chamber, wherein the solvent is separated from the vacuum by a gas-permeable membrane or a gas-permeable tube. The dissolved gases, unlike the liquid, can diffuse through the membrane to the vacuum side. Thus, the more dissolved gas is removed from the solvent the longer it remains in the vacuum chamber. The basic method has been known for a long time and is mentioned in the following patents, which deal with specific embodiments: DE 4139735 C3, DE

4446270 C1, DE 69828594 T2, EP 1529560 B1.

A fundamental problem of online vacuum degassing is that not only dissolved gases, but also solvent vapors can pass through the membrane. As a result, especially volatile components of the solvents are extracted through the membrane (selective extraction). For premixed solvents, selective extraction causes an undesirable, gradual change in the solvent composition, especially if the solvent lingers in the vacuum chamber for a long time. This is especially the case when HPLC operates at very low flow rates ranging from a few tens of n / min to several μ / min (nano-HPLC). Nano-HPLC pumps usually only absorb new solvent at longer intervals, so that the solvent in the vacuum chamber stands still most of the time. This leads to particularly strong selective extraction and variations in the solvent composition. Because of these problems, nano-HPLC usually does not use on-line vacuum degassing.

US Pat. No. 4,133,767 discloses a degassing process in which a stream of fine helium bubbles is passed through the solvent in the solvent bottle (helium sparging). The helium itself is only slightly soluble, but it carries other dissolved gases out of the liquid. This process is less efficient and relatively expensive because of the continuous helium demand, also volatile solvent components are also removed here in addition to the dissolved gases, which, similar to the online vacuum degassing can lead to a change in the solvent composition. For these reasons, helium sparging is used only in exceptional cases.

A pre-degassing of solvents would be possible for example by heating, filtering, sonication, vacuum treatment (offline vacuum degassing) or a combination of these methods. However, when the solvent in the solvent bottle is subsequently exposed to the ambient air, gases again diffuse into the liquid until an equilibrium state re-establishes. Because of this Wiederbegasung the effect of Vorentgasung is not permanent, therefore, the solvent must be prepared according to frequently fresh.

Also, to avoid problems due to selective evaporation, the solvent must be freshly prepared accordingly often. This causes additional expense.

The present invention is therefore based on the object for the HPLC, in particular for nano-HPLC, to provide a solvent storage system which is suitable for an uninterrupted service life of several days to weeks, without the need for user interaction (such as renewal of the solvents ).

This object is achieved by a method with the features of claim 1, by a device having the features of claim 7 and by the use of a syringe with the features of claim 12.

According to the invention, the respective solvent in the at least one reservoir is almost completely sealed off from the ambient air, whereby air inclusions can already be avoided during filling or eliminated after filling. By reducing the container volume in the delivery (and corresponding increase in the container volume during filling) of solvent therein while continuous gas-tight closure relative to the ambient air can advantageously not only a previously degassed solvent recorded but also protected over the said operating time before Wiederbegasung from the ambient air become.

Since the gas exchange between the solvent and the ambient air according to the invention is prevented in both directions, not only a Wiederbegasung, but also a selective evaporation can be advantageously avoided.

In a preferred embodiment of the invention, the solvent is discharged from the at least one storage container to a conveyor, in particular a pump of an HPLC system, substantially without negative pressure or sucked by the pump without a negative pressure in the reservoir or in connecting lines. As a result, in addition to the advantages explained above, it is also avoided that by reducing the pressure (eg by suction vacuum of the Pump) dissolved gases become gaseous again and form bubbles that can affect the function of the pump.

The variability of the container volume can for example be realized in a simple manner with a rigid container body with preferably straight container wall or with a constant cross-sectional profile in which a movable lid or closure the container interior gas-tight in each volume state. Here, the lid may be formed, for example, as a float or piston, which engages with its Au ßenumfang in the inner circumference of the body so that it is indeed free to move, but still largely gas-tight manner (fit with minimal play).

In a preferred embodiment of the invention, the lid can be preloaded with a (small) compressive force that can be applied, for example, by spring force or weight. The pressure built up thereby in the container ensures, for example, that the pump reliably sucks in solvent even if the pump itself has not yet been vented.

In a further embodiment, it is also conceivable that at least one elastic sealing element is located between the cover outer circumference and the basic body inner circumference. This has the advantage that there is virtually no gap through which gases could diffuse into or out of the solvents. To achieve this advantage, the sealing element itself is also sufficiently diffusion-tight. Although a certain amount of friction is created by the elastic sealing element, with a sufficiently large piston cross section, a low negligible intake negative pressure in the permissible range is sufficient to overcome this friction. In addition, in containers with an elastic sealing element, an applied force (preload) explained above can compensate for the friction on the seal.

In a particular embodiment of the invention, the at least one reservoir is filled with solvent without air or vented after filling by squeezing out the air. The solvents are, as far as necessary for the application, premixed in the usual way. In addition, the solvents may preferably before the Use to be pre-degassed using known methods. For this purpose, preferably offer such degassing, which can be carried out directly in the solvent bottle, ie ultrasound, heat, offline vacuum degassing or combinations of these methods.

In a particularly preferred embodiment of the invention, syringes made of substantially gas-impermeable material, such as glass, are used as the solvent container. Suitable are e.g. so-called all-glass syringes, in which both the cylinder and the piston are made of glass, without the need for further sealing elements. Of course, it is also conceivable to use syringes with elastic sealing elements between the piston and cylinder. The pre-degassed solvents are filled in the syringes or raised by piston movement. Eventually in the syringes with trapped air can be pushed out below. Furthermore, the syringes are connected to the HPLC system via gas-diffusion-tight connection hoses.

Of course, instead of glass, the syringes and the aforementioned containers can also be made of other materials, such as metal, ceramic, gas-tight plastics, etc., provided that they meet the requirements of chemical resistance and gas-tightness. However, composite materials, such as e.g. metal-coated plastics. This offers the advantage that the positive properties of the different materials, e.g. Unbreakability and low gas permeability, can be combined. In principle, the effect according to the invention can also be achieved in that, instead of movable lids in rigid container base bodies, the solvent containers themselves are wholly or partly yielding, e.g. in the form of bags or of containers with deformable membranes. For the realization of such embodiments are offered to plastics or elastomers, which, however, are not usually sufficiently diffusion-tight. Although the practical implementation of such

Embodiments therefore made difficult, it is not impossible with appropriate choice of material (for example, metal-coated plastics or the like). In a further embodiment of the invention, the effect is taken into account that the movement of the lid, in particular the piston of the syringes, is directly related to the solvent consumption. For this purpose, the position of the piston is detected by mounting (on, in the container or in the vicinity of the container) of displacement or position sensors, the known principles, such as optical, inductive, capacitive or magnetic sensors as well as mechanical switches o. ä. are usable. In this way, the level of the syringe and thus the amount of solvent still available can be determined. In the simplest case, a signal is given only when falling below a certain level, for example, can trigger an alarm or stop the pump. With more sophisticated sensors that measure the position of the piston within a working area, a continuous monitoring is also feasible. For example, based on a discrepancy between solvent consumption and solvent release of the pump, the leak rate of the pump can be determined.

In the case of solvents which must be protected from light to counteract algae formation or chemical changes, light protection may be achieved by using colored or opaque containers, in particular syringes, or by using an appropriate cover.

In order to ensure a solvent supply for a service life of several days to weeks, it is sufficient in HPLC, in particular nano-HPLC, with low flow rates used in the range of some 10 nl / min to several μΙ / min, containers, in particular syringes, with a useful volume between about 10 ml and 250 ml, eg 100 ml to use. As a result, the above-explained

Benefits over the entire operating life achieved.

Further advantageous embodiments of the invention will become apparent from the dependent claims. The invention will be explained in more detail with reference to the embodiments illustrated in the drawings. In the drawing show:

Fig. 1 is a schematic view of a nano-HPLC pump with two storage containers according to the invention;

Fig. 2 is an enlarged partial view of the structure of FIG. 1 and

Fig. 3 is a schematic partial view of two reservoirs according to the invention with additional filter elements.

1 shows a preferred embodiment of the invention for a binary nano-HPLC pump 3, ie a nano-HPLC pump, which operates with two different solvents 100a and 100b. The solvents 100a and 100b are located in the syringes 1 a and 1 b serving as storage containers, preferably all-glass syringes with, for example, 100 ml nominal volume, which are connected to the inlets 3a and 3b of the pump 3 via connecting lines 2a and 2b. A solvent supply of 100 ml is sufficient in nano-HPLC systems for a service life of several days to weeks, which of course smaller volumes of a few ml, for example 1 ml to 10 ml or up to 50 ml, are suitable for this purpose. For higher flow rate systems, correspondingly larger volumes of, for example, 200 ml to 500 ml may be used.

For pumps with more or less than two solvent channels, more or fewer syringes and connecting lines may be provided accordingly. The pump 3 mixes and doses the two solvents 100a and 100b as required by the particular application and provides at its outlet 3c the solvent mixture for the rest of the HPLC system. This is indicated by the arrow 4. As syringes 1 a and 1 b, and for any other necessary syringes Ganzglasspritzen can preferably be used, which are advantageously available as a mass-produced product cost. Advantageously, glass syringes are resistant to the solvents customary in HPLC, easy to clean and donate almost no impurities to the solvent. The use of relatively large (1 ml to 10 ml, up to 50 ml and up to 100 ml or even up to 250 ml) Ganzglasspritzen has in addition to the advantages mentioned above, the further advantage that the piston cross section is relatively large - for example the piston cross-section with a syringe volume of 100 ml several cm ² . If due to dirt between the piston and cylinder friction occurs, this can be easily overcome by the externa ßeren air pressure due to the relatively large piston cross section. Furthermore, in sealless Ganzglasspritzen the piston is very smooth, so that the piston movement is not hindered by friction forces. Thus, no or no appreciable negative pressure is created during suction.

The vertical arrangement of the syringes 1 a, 1 b shown in the drawings with the downwardly directed connection piece 13 is expedient, but not mandatory.

In the following, the exact operation of the invention and the structure of the syringes 1 a and 1 b will be explained with reference to FIG. 2. Here, the following features 1, 2 and 100 correspond to the features 1 a, 1 b; 2a, 2b and 100a, 100b. The remaining features 10-14 shown in Fig. 2 are for the in the syringes 1 a and 1 b, of course, also identical features present.

The all-glass syringe 1 (as an enlarged example of the syringes 1 a and 1 b) has a sufficiently large useful volume of, for example, 1 ml to 10 ml, or 10 ml up to 250 ml, preferably 100 ml, to a solvent supply for an operating time of an HPLC system from several days to weeks. In the syringe 1 is the previously degassed solvent reservoir 100th

The syringe 1 has a downwardly directed in the drawing connecting piece 13, to which a gas-tight line 2 is connected. This gas-tight line 2 leads to the pump 3 to be supplied (shown in FIG. 1), the direction of flow of the solvent 100 in the line 2 being indicated by the arrow 20. The syringe 1 consists of a cylinder 10, whose interior is closed at the top by the also made of glass piston 1 1. Both parts are made that between the inner circumference of the cylinder 1 1 and Au ßenumfang of the likewise cylindrical piston 1 1 only an externa ßer narrow circumferential sealing gap 12 and a cylindrical gap surface (in the form of a cross section formed in the annular gap) remains, the or the sealing effect of the syringe 1 ensures. This gap 12 is shown in Fig. 2 only for better visibility excessively wide.

The material of cylinder 10 and piston 1 1 and the connecting line 13 connected to the connection line are gas-impermeable, therefore, a gas exchange between solvent and ambient air could possibly take place along the sealing gap 12 between the cylinder and piston. However, this circumferential sealing gap is dimensioned as narrow as possible and therefore represents an extremely narrow and comparatively long path between the solvent 100 and the ambient air. Thus, there is almost no gas exchange between the solvent 100 and the ambient air. When the HPLC pump 3 aspirates solvent, the solvent volume 100 contained in the syringe 1 is reduced. As a result, the freely movable piston 1 1 moves according to, as indicated in Fig. 2 by the arrow 14. Thus, during this process, no air enters the syringe 1, and there is no or at least no appreciable negative pressure. The solvent 100 contained in the syringe 1 remains closed by the outside air.

In addition, the syringes 1 and 1 a and 1 b largely prevent the ingress of dirt, such as dust or liquid droplets from the ambient air, to the solvents. As a result, undesirable contaminations of the solvents 100 or 100a and 100b can advantageously be avoided.

The filling of the syringes can be done manually in the simplest case by the connecting piece 13 is held either directly or via a connecting line in the container with the vorentgasten solvent and then the desired solvent volume is sucked by operating the piston 1 1. Subsequently, if necessary mitged-sucked air can be forced out of the syringe, as this could otherwise go into solution over time. Thereafter, the connecting line 2 is connected to the connecting piece 13 again. For a more convenient filling additional devices such as shut-off valves and branching can be switched into the connecting line 20. This makes it possible to prevent air from being introduced during normal filling, so that venting is only necessary when filling for the first time. Likewise, the filling can be done by a pump.

In HPLC, filter elements are usually incorporated into the suction path of the pump to keep particles present in the solvent from the pump. Most of these filter elements are attached directly to the suction lines and thus hang in the solvent containers. This is not readily possible with the solution according to the invention.

Instead, as shown in Fig. 3, filter elements 5a, 5b are expediently inserted between the syringes 1 a, 1 b and the pump 3 in the connecting lines 2a, 2b. In the solution shown in Fig. 3, the filter elements are attached, for example, directly to the syringe or its connection piece 13.

Of course, it is also conceivable to interpose filter already when filling the syringes in order to prevent any particles from getting into the syringes. However, these must then be omitted or reversed during operation, since the flow direction (recording direction to discharge direction) then reverses.

List of Reference Numerals, 1a, b Ganzglasspritzen

, 2a, b connecting lines

Nano-HPLC-pump

c output

Arrow towards the rest of the HPLC systema, b filter elements

0 cylinder

1 piston

2 sealing gap

3 connecting pieces

0 arrow for the flow direction of the solvent 100, 100a, 100b solvent

Claims

claims

1 . Method for supplying HPLC systems with at least one solvent (100, 100a, 100b), characterized in that the solvent (100, 100a, 100b) is dispensed from at least one gas-tightly sealed storage container (1, 1a, 1b), wherein the volume of the container decreases as the solvent (100, 100a, 100b) exits the container.

2. The method according to claim 1, characterized in that the solvent (100, 100a, 100b) from the at least one storage container (1, 1 a, 1 b) to a conveyor (3) of an HPLC system is discharged substantially without negative pressure ,

3. The method according to claim 1 or 2, characterized in that the container volume decreases by moving in a rigid container base body (10) movable cover (1 1) in the direction of the container interior.

4. The method according to any one of the preceding claims, characterized in that the at least one storage container (1, 1 a, 1 b) is filled without air or is vented after filling by squeezing out the air.

5. The method according to claim 3 or 4, characterized in that the movable lid (1 1) is biased a low compressive force in the direction of the container interior.

6. The method according to any one of claims 3 to 5, characterized in that the movement of the lid (1 1) is detected to monitor the level and / or the emptying and / or filling process.

7. An apparatus for performing the method according to any one of the preceding claims with at least one reservoir (1, 1 a, 1 b), characterized in that the at least one reservoir (1, 1 a, 1 b) is gas-tight and from the at least a reservoir (1, 1 a, 1 b) a solvent contained therein (100, 100a, 100b) can be discharged, wherein the container volume decreases to the same extent as the solvent (100, 100a, 100b) from the container (1, 1 a, 1 b) emerges.

8. The device according to claim 7, characterized in that the at least one storage container (1, 1 a, 1 b) consists of a rigid container base body (10), in which a container interior of the final and the container volume variable movable lid (1 1) located.

9. Apparatus according to claim 8, characterized in that the container base body as a cylinder (10) and the lid as a piston (1 1) or float is formed.

10. The device according to claim 8 or 9, characterized in that the lid (1 1) is biased with a small pressure acting on the container interior compressive force.

1 1. Device according to one of claims 8 to 10, characterized in that on or in the at least one storage container (1, 1 a, 1 b) at least one sensor is arranged to detect the movement of the lid (1 1).

12. Use of a syringe (1, 1a, 1b), with at least one cylinder (10) made of glass, as a storage container (1, 1a, 1b) according to one of claims 7 to 11.