How to calibrate Viscotek GPC/SEC detectors for protein measurements

This note describes how to calibrate a Viscotek SEC system with a sample such as BSA. Bovine serum albumin contains oligomers which separate well under most chromatographic conditions. It is therefore an excellent choice for a standard

Calibration Procedure

Bovine serum albumin (BSA) is a cheap and readily available protein which separates well under most chromatographic conditions. It is therefore an excellent choice for a standard. However, it has a high propensity to form oligomers and these are normally resolved by the chromatography. The instructions below describe how to calibrate a Viscotek SEC system with a sample such as BSA.

Carefully creating a method takes just a few minutes and following this protocol will ensure that calculated results are as accurate and reliable as possible. Once the method is created, it takes just seconds to analyze the subsequent samples.

Open the data file to be used as the standard in OmniSEC. The concentration of the standard sample should have been known and input when the sample was run. The accuracy of this initial concentration is very important. Check that all detectors show good signal quality, and then add all of the detectors to the display by selecting the detector buttons (if using OmniSEC version 4.6, hold Ctrl while selecting the detectors). Set the baseline and integration limits around the entire protein sample using the right-click menu, and then select the 'Method - New' option from the main menu (figure 1).

Figure 1: Set limits and baselines around all the peaks in the standard protein sample and select 'New' in the 'Method' menu.
MRK1664 fig1

Setting baselines and limits

Setting baselines and limits can be done by right-clicking on the 'Acquired Data View' and selecting the appropriate options. A quicker way to set limits and baselines is with the shortcut keys. Holding down the 'shift' key and left clicking in the Acquired Data View' will drop a limit at that elution volume on all of the detector chromatograms. A second left-click at a different location will drop the second limit. Holding down the 'shift' key and right clicking will place baselines on all of the detector chromatograms. If the 'control' key is held down, instead of 'shift', then the limits or baselines will only be placed on the active channel. To remove limits and baselines, select the appropriate option from the right-click menu.

Calibration Procedure

In the 'Create New Method' window, select the 'Blank' option, and then select in the 'Multi-Detectors-Homopolymers' option. The next screen will show the detectors to be calibrated. Select the concentration detector, either refractive index (RI) or ultraviolet (UV), and then click 'Next'. Enter the known parameters for the protein standard in the 'Standard' window. Those for BSA are shown in figure 2. Note, that the 2nd virial coefficient and intrinsic viscosity values are not required. However, if the values are known, they can be entered here. If the UV detector is used, the dA/dc value is equivalent to the extinction coefficient presented as A280 = X ml mg-1 cm-1 (The value at 1% can be used as long as this is consistent with the sample tab). The molecular weight value that should be entered here is that of the monomeric species (figure 2).

Figure 2: Follow the method wizard by filling in the above options and clicking 'Next' at each step.
MRK1664 fig2

Protein dn/dc is typically constant at 0.185 ml/g.

After entering the standard properties, click 'Next', and then fill in the appropriate values in the 'Sample' window (figure 3). In the sample window, the box labeled 'Calculate concentration from detector' must be checked. To complete the initial calibration keep the 'peak detection' algorithm set to Manual and then save the calibration with an appropriate name. After saving, the software will ask 'Calibrate the method now?' Click 'Yes' and the calibration results will be displayed.

(If limits have not already been set, a different message will appear - click 'OK', set limits and baselines as described earlier and then select 'Calibrate!' from the 'Method' menu.)

Figure 3: Continue to follow the measurement wizard through to the end and calibrate the system.
MRK1664 fig3

The peaks are aligned and the detector calibration constants reported in the 'Result View' (figure 4).

Figure 4: After calibration, the calibration results including instrument constants and offsets will be displayed.
MRK1664 fig4

For a single component standard, such as low polydispersity polystyrene, this would complete the detector calibration. However for a multi-component standard, such as BSA, a second stage is required to correct for the fact that the sample has formed some oligomers.

For the next stage, right click the chromatogram and select the 'Clear LIMITS on ALL Channels' or the 'Delete All Limits' option. Zoom in on the monomer peak and set the integration limits around only the monomer peak using the 'Add limits on all Channels' option in the right click menu (figure 5).

Figure 5: Delete the original limits then zoom in on the monomer peak and set new limits around just this peak.
MRK1664 fig5

Note that the calculated values in the results window represent the sample within the selected limits. As evident in figure 5, the molecular weight results for this 66 kDa monomer are incorrect. This is a consequence of using the monomer molecular weight to represent the weight average molecular weight for the entire sample in the original calibration.

Scroll down in the 'Results View' to the calculated Sample Concentration, press F3 to open the 'Run Parameters' window (or use the File-Run Parameters), and then enter the calculated Sample Concentration in the New Concentration field. Press OK, then recalibrate by selecting the Method-Calibrate option from the Main Menu tool bar.

Figure 6: Scroll down in the 'Result View' to the calculated concentration. Copy this value into the new concentration box in the run parameters dialogue (F3). Click ok and re-calibrate.
mrk1664_figure06

Once the recalibration is completed, it is always a good idea to review the calibration results. Figure 7 shows the calibration results for the example presented here. The Cal Factors shown are indicative of typical values for detector calibration constants, as are the Sigma and Tau values. Sigma, indicative of band broadening, should be around 0.2, and Tau, indicative of tailing, should be smaller than Sigma.

Figure 7: Typical calibration results after the second stage calibration
MRK1664 fig7

As a final check of the calibration results, it is instructive to treat the standard measurement results as an unknown, to see if the calibration yields the expected results. Also, the dimer molecular weight should be accurately calculated by the method.

In the Acquired Data View, add limits around the dimer peak and if the result is not automatically re-calculated, click 'execute' or press F5. The results should now show two columns representing the two peaks. The monomer peak should have a molecular weight very close to that which was input in the standard options (in the case of BSA, 66 kDa) and the dimer peak should have a molecular weight of twice the monomer (133 kDa). Depending on the BSA sample and the resolution, a third peak may be visible representing the trimer and this peak should have a molecular weight of three times the monomer (201 kDa).

The molecular weight traces in the Derived Data View should be plateaus indicating that each peak is monodisperse (to view all peaks together, right click in the 'Derived Data View' and select 'All Peaks Mode' or 'Peak by Peak Mode'). This is the equivalent of the Mw/Mn value in the results table. This value should be close to 1 and is typically less than 1.05. For a mixture of protein oligomers, this is the type of result that one would expect, with each peak showing a constant molecular weight.

Figure 8: After the second calibration, the molecular weights of all of the peaks should be correctly calculated.
MRK1664 fig8

The calibration is now complete and the method can be used to analyze other protein samples. It is best practice to run a standard and calibrate at the beginning of each set of measurements. If calibration every time is not required, then at the very least, a standard should be run and analyzed with the existing method to ensure it is working properly.

To analyze the next sample in the sequence, press F12 to move to the next file or open the sample of choice using the 'File - Open' menu. The file to be analyzed must be in the same folder as the standard. Set limits and baselines around the peak and click 'Execute' or press F5. The sample will be immediately analyzed using the method created.

Figure 9: Set limits and baselines around the peak and click 'Execute' or press F5 to run the method.
MRK1664 fig9

Background information

It is important to understand "what" is being calibrated during this process. The calibration procedures within the Viscotek OmniSEC software perform two functions.

  1. Calibration constants - All detectors generate a voltage output, and in order for the output signal to be correlated with a physical property change, the mathematical relationship between the absolute change in the physical property and the change in the detector voltage output must be established. For many GPC detectors, such as refractive index (RI) & ultraviolet spectroscopy (UV) detectors, the relationship between changes in the physical property being measured and the voltage output is linear, with the calibration using a standard of "known" properties producing a calibration constant. Determination of the calibration constants is the 1st function performed during the OmniSEC calibration procedure.

  2. Offset Volume and band broadening - In multi-detector GPC systems, the signals from multiple detectors are coupled to give the maximum amount of data. However, in order to couple these signals, the elution peaks must be aligned and corrected for band broadening, such that the same elution "slice" is being used in the calculations. The 2nd function performed during the OmniSEC calibration is therefore to calculate the offset volume between the GPC detectors and correct for inter-detector band broadening.

There are a variety of GPC detector calibration standards available, either from Viscotek or 3rd party vendors. When selecting an appropriate calibration standard, there are three things to consider.

  • The standard must be suitable for use under the conditions that are to be employed when measuring unknown samples. For example, if the experimental objective is general protein characterization using a Superdex 200 column with an upper molecular weight limit of 600 kDa, a low molecular weight aqueous standard would be appropriate.
  • All of the injected standard's mass must pass or elute from the column. The voltage response from the concentration detectors is proportional to the sample concentration, and the calibration constant is calculated from the entire standard peak area whose concentration is known if 100% of the sample mass elutes. If the entire injected sample does not elute from the column, an error will be introduced into the calibration constant.
  • The calibration standard should have a polydispersity of no more than 1.1. As noted above, the response from the concentration detectors is proportional to the sample concentration. The response from the light scattering (LS) detector however, is a function of both the concentration and the molecular weight. If the molecular weight varies too much across the elution peak, as would be expected for samples with Mw/Mn significantly greater than 1.1, improper alignment of the LS and RI/UV peaks can lead to error in the off-set volume calibration.

When it comes to protein measurements, the requirements for calibration of the GPC detectors are no different. The caveat is that there is currently no protein standard that satisfies the low polydispersity requirement, as proteins tend to form oligomeric structures in solution. While one could select a low molecular weight synthetic polymer standard, identifying one that is compatible with the chromatography and has Mw/Mn of close to 1 is difficult. An alternative approach is to use a two step calibration technique which facilitates calibration of the GPC detectors using a readily available standard protein that can be resolved into its separate oligomer populations.

Using this technique, the concentration detectors are calibrated first by treating the entire sample as a single entity. In the second step the concentration of the monomer peak is calculated and then the monomer alone is used to calibrate the light scattering detectors.

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