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Impact of stationary-phase pore size on chromatographic performance using oligonucleotide separation as a model

Joakim Bagge, Martin Enmark, Marek Leśko, Fredrik Limé, Torgny Fornstedt, Jörgen Samuelsson

2020Journal of Chromatography A31 citationsDOIOpen Access PDF

Abstract

A combined experimental and theoretical study was performed to understand how the pore size of packing materials with pores 60-300 Å in size affects the separation of 5-50-mer oligonucleotides. For this purpose, we developed a model in which the solutes were described as thin rods to estimate the accessible surface area of the solute as a function of the pore size and solute size. First, an analytical investigation was conducted in which we found that the selectivity increased by a factor of 2.5 when separating 5- and 15-mer oligonucleotides using packing with 300 Å rather than 100 Å pores. We complemented the analytical investigation by theoretically demonstrating how the selectivity is dependent on the column's accessible surface area as a function of solute size. In the preparative investigation, we determined adsorption isotherms for oligonucleotides using the inverse method for separations of a 9- and a 10-mer. We found that preparative columns with a 60 Å-pore-size packing material provided a 10% increase in productivity as compared with a 300 Å packing material, although the surface area of the 60 Å packing is as much as five time larger.

Topics & Concepts

ChemistryChromatographySelectivityAdsorptionSpecific surface areaOligonucleotidePhase (matter)RodFunction (biology)Organic chemistryEvolutionary biologyMedicinePathologyCatalysisBiochemistryBiologyAlternative medicineDNAAnalytical Chemistry and ChromatographyMicrofluidic and Capillary Electrophoresis ApplicationsProtein purification and stability
Impact of stationary-phase pore size on chromatographic performance using oligonucleotide separation as a model | Litcius