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UHPLC Separations using HPLC Methods and TSKgel® Columns

PostPosted: Wed 27 Jul 2016 14:37
by Interchim
UHPLC Separations using HPLC Methods and TSKgel® Columns
TOSOH
Application n°a15l58a

Introduction
The use of UHPLC systems for small molecule analysis has gained widespread acceptance among researchers in recent years. A UHPLC system is a HPLC system optimized with regards to dead volume, injection performance, and detector sampling rate and is able to tolerate application pressures exceeding 1,000 bar. It is therefore advantageous to use UHPLC instrumentation for methods developed on conventional HPLC systems with HPLC columns. The use of HPLC columns with UHPLC systems offers the advantages of cost and time savings over having to purchase and develop new methods with UHPLC columns. This application note demonstrates the excellent performance of conventional TSKgel HPLC columns on a UHPLC system.


Experimental Conditions
Column: TSKgel SP-STAT, 7 μm, 4.6 mm ID × 10 cm Systems: Dionex UltiMate® 3000 HPLC System (equipped with Dionex UVD 170S Detector) Dionex UltiMate 3000RS UHPLC System
Mobile phase: A: 10 mmol/L sodium phosphate, pH 7.0
B: 10 mmol/L sodium phosphate, pH 7.0, + 1 mol/L sodium chloride Gradient: 0-50% B in 25 min
Flow rate: 1.0 mL/min
Detection: UV @ 280 nm
Injection vol.: 5 μL
Sample: monoclonal lgG, 1 mg/mL
Column: TSKgel G2000SWXL, 5 μm, 7.8 mm ID × 30 cm
Systems: Dionex UltiMate 3000 HPLC System (equipped with Dionex UVD 170S Detector) Dionex UltiMate 3000RS UHPLC System
Mobile phase: 0.1 mol/L sodium phosphate, pH 6.7 + 0.1 mol/L sodium sulfate
Flow rate: 1.0 mL/min
Detection: UV @ 280 nm
Injection vol.: 20 μL
Samples: para-aminobenzoic acid, thyroglobulin, γ-globulin, ovalbumin, ribonuclease A, 2 mg/mL each


Results and Discussion
Figure 1 shows the analysis of a monoclonal lgG using a TSKgel SP-STAT cation exchange column. The same column, sample, and method were used to verify the column-system compatibility on both the HPLC (blue chromatogram) and UHPLC (red chromatogram) systems. The column performs better in the UHPLC system than it does when connected to the HPLC system. The number of theoretical plates is 6% higher for the UHPLC setup.

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FIGURE 1_Analysis of a Monoclonal lgG using a TSKgel SP-STAT Column and a Zoomed Elution Profile of the mAb Charge Variants on the TSKgel SP-STAT column

Figure 2 shows a zoomed elution profile of the mAb charge variants on the TSKgel SP-STAT column, which provides better insight into what extent the elution profile benefits from using a UHPLC system.

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FIGURE 2_Analysis of a Monoclonal lgG using a TSKgel SP-STAT Column and a Zoomed Elution Profile of the mAb Charge Variants on the TSKgel SP-STAT column

The peak width is smaller for the UHPLC chromatogram. The decreased system dead volume resulted in the peak elution to occur earlier than it did on the HPLC system.

Figure 3 shows a standard protein mixture analyzed using a TSKgel G2000SWXL size exclusion column. The number of theoretical plates exceeds 32,000 for para-aminobenzoic acid when connected to the UHPLC system (blue chromatogram), while the column connected to the HPLC system (red chromatogram) only reaches 29,000 for the same component.

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FIGURE 3_Separation of a Standard Protein Mixture using a TSKgel G2000SWXL Column

Of course, resolution is an important factor when considering chromatographic performance. The HPLC data shows a resolution of 2.1 for the separation of γ-globulin and ovalbumin, and 10.2 for ribonuclease A and para-aminobenzoic acid. For the UHPLC data, the resolution factors increase to 2.2 and 10.9 for the respective peak pairs.


Conclusions
The results of both analyses using a TSKgel SP-STAT ion exchange column and a TSKgel G2000SWXL size exclusion column indicate excellent separation with high resolution when used on a UHPLC system. As a UHPLC system is simply an optimized HPLC system, bioseparation method transfer from HPLC to UHPLC is hardly more complicated than from one HPLC instrument to another. The applied pressure in these applications was far from exceeding the limit of a conventional HPLC system. This is the case in most bioseparation applications, since many biological sample molecules themselves cannot withstand very high pressure. Transferring established HPLC methods using HPLC columns to a UHPLC system is an economical and time-saving way to take advantage of this latest wave of development in HPLC technology.

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