Preparative columns

For applications in the field of preparative chromatography, MZ-Analysentechnik GmbH supplies ready-packed HPLC columns with almost the entire range of chromatographic materials in dimensions from 8.0 to 50.0 mm ID (semi-prep - prep). In the manufacture of our in-house preparative columns, we use a specially optimised packing procedure for each packing material and each pre-packed preparative column is then checked to ensure that it meets our strict quality requirements.

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PerfectSil Target ODS-3 3µm 250x20mm HPLC Column

MZ0802-250200

Product Type: HPLC Column Length: 250 mm Internal Diameter: 20 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target ODS-3 3µm 250x10mm HPLC Column

MZ0802-250100

Product Type: HPLC Column Length: 250 mm Internal Diameter: 10 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target ODS-3 3µm 150x10mm HPLC Column

MZ0802-150100

Product Type: HPLC Column Length: 150 mm Internal Diameter: 10 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target ODS-3 3µm 250x8,0mm HPLC Column

MZ0802-250080

Product Type: HPLC Column Length: 250 mm Internal Diameter: 8.0 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target ODS-3 3µm 150x8,0mm HPLC Column

MZ0802-150080

Product Type: HPLC Column Length: 150 mm Internal Diameter: 8.0 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target ODS-3 3µm 100x8,0mm HPLC Column

MZ0802-100080

Product Type: HPLC Column Length: 100 mm Internal Diameter: 8.0 mm Particle Size: 3 µm Pore Size: 100 Å Chemistry: C18 (RP-18, ODS, Octadecyl) USP Class: L1 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: endcapped Carbon Load: 17.0 % Bet Surface Area [m2/g]: 450.0 Mode of Separation: Reversed Phase Chromatography (RP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target 100 Sil 5µm 250x40mm HPLC Column

MZ0800-250400

Product Type: HPLC Column Length: 250 mm Internal Diameter: 40 mm Particle Size: 5 µm Pore Size: 100 Å Chemistry: Silica USP Class: L3 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Preparative Column Endcapping: non endcapped Bet Surface Area [m2/g]: 450.0 Mode of Separation: Normal Phase Chromatography (NP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target 100 Sil 5µm 250x30mm HPLC Column

MZ0800-250300

Product Type: HPLC Column Length: 250 mm Internal Diameter: 30 mm Particle Size: 5 µm Pore Size: 100 Å Chemistry: Silica USP Class: L3 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Preparative Column Endcapping: non endcapped Bet Surface Area [m2/g]: 450.0 Mode of Separation: Normal Phase Chromatography (NP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target 100 Sil 5µm 250x20mm HPLC Column

MZ0800-250200

Product Type: HPLC Column Length: 250 mm Internal Diameter: 20 mm Particle Size: 5 µm Pore Size: 100 Å Chemistry: Silica USP Class: L3 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Preparative Column Endcapping: non endcapped Bet Surface Area [m2/g]: 450.0 Mode of Separation: Normal Phase Chromatography (NP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

PerfectSil Target 100 Sil 5µm 250x10mm HPLC Column

MZ0800-250100

Product Type: HPLC Column Length: 250 mm Internal Diameter: 10 mm Particle Size: 5 µm Pore Size: 100 Å Chemistry: Silica USP Class: L3 Manufacturer: MZ-Analysentechnik GmbH Delivery Time: approx. 1-2 days Column Type: Semi-preparative Column Endcapping: non endcapped Bet Surface Area [m2/g]: 450.0 Mode of Separation: Normal Phase Chromatography (NP) Hardware Type: Ready-to-use Column Matrix: Silica Particle Morphology: spherical, fully porous pH Minimum: 2.0 pH Maximum: 8.0 Pressure Stability: 400 bar Technology: HPLC Temperature Maximum [°C]: 60

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Technical Data

How do I choose the right preparative column?

In principle, the stationary phase should already be defined. Normally, experiments are carried out with analytical columns and these methods are then scaled up to the preparative scale. It is important to ensure that the particle size ideally remains the same. If a larger particle size is used for the preparative column, it is advisable to maintain the ratio of particle size to column length. In addition, the mobile phase and the solvent of the sample should also be identical.

Therefore, when selecting the correct preparative column, the question of which dimension is required should be asked. As maximum loadability is desired in preparative chromatography, it is advisable to first optimise the analytical method and achieve the highest possible resolution. Once the highest resolution has been achieved, the loadability can be analysed:

A sample with a high concentration is prepared and the injection volume is increased.
Several samples with different concentrations are prepared and the injection volume remains constant

This should maximise the sample quantity so that the peaks to be separated can still be separated with sufficient purity. This maximum loadability varies from column to column and is highly dependent on the individual separation problem and resolution. This loadability must therefore be determined empirically for each separation. The resulting poor peak shapes or overloading of the detector can be ignored during such preparative preparation.

The maximum loading capacity of the analytical column has been determined - what happens now?

Once the maximum load (defined amount of analyte in a defined injection volume) has been determined, you should consider how much of the analyte should be separated in one run. This injection volume can then be used to calculate the appropriate internal diameter using the following formula. If the particle size of the analytical and preparative column is identical and therefore the length remains the same, the length term becomes one and can be neglected.

V_{Inj,Prep} = V_{Inj,Analy} - (\frac{L_{Prep} - {dc}_{Prep}^{2}}{L_{Analy} - {dc}_{analyte}^{2}})

Further adjustments

With the appropriate inner diameter of the preparative column, the remaining parameters such as the flow velocity and possibly the gradient time can also be calculated.

Adjusting the flow velocity

F_{Prep} = F_{Analy} - (\frac{{dp}_{Analy} - {dc}_{Prep}^{2}}{{dp}_{Prep} - {dc}_{Analy}^{2}})

Adjustment of the gradient

Different systems are often used for an analytical and preparative method. This also results in different dwell and dead times (dwell volume and dead volume). To compensate for this, short isocratic steps can be incorporated at the start of the gradient. The following equation applies to gradients that are transferred from one system to another:

\frac{t_{D,Analy} + t_{I,Analy}}{t_{c,Analy}} = \frac{t_{D,Prep} + t_{I,Prep}}{t_{c,Prep}}

tD_,Analy Dwell time for the analytical system

tI_,Analy Time of the isocratic step at the beginning of the gradient for the analysed system system

tc_,Analy Dead time for the analytical system

tD_,Prep Dwell time for the preparative system

tI_,Prep Time of the isocratic step at the beginning of the gradient for the prep. system system

tc_,Prep Dead time for the preparative system

Compensation of different dwell volumes of both systems

In order to compensate for different residence volumes between an analytical and preparative system, short isocratic steps can be incorporated before the actual gradient. The time of such a step can be calculated using the following formula, whereby the residence volumes as well as the column dead volume must be known for both systems.

t_{I,Prep} = (\frac{t_{I,Analy} - F_{Analy}}{ν_{C,Analy}} + \frac{ν_{D,Analy}}{ν_{C,Analy}} - \frac{ν_{D,Prep}}{ν_{C,Prep}}) - \frac{ν_{C,Prep}}{F_{Prep}}

tI_,Prep Time of the isocratic step at the beginning of the gradient for the prep. system. system

tI_,Analy Time of the isocratic step at the beginning of the gradient for the analy. system system

_FPrep Flow rate for the preparative system

_FAnaly Flow rate for the analytical system

vC_,Prep column dead volume for the preparative system

vD_,Prep Dwell volume for the preparative system

vC_,Analy column dead volume for the analytical system

vD_,Analy Residual volume for the analytical system

With all these calculations, you can scale up your analytical method to a preparative method. In this process you can also use our HPLC method transfer tool can also support you in this process. We are also happy to help you with the calculations. Get in touch with us! At MZ-Analysentechnik GmbH, you can also obtain any material as a preparative column to ensure seamless scaling from analytical to preparative methods.

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