Abstract

Continuous stationary phase gradients for liquid chromatography (LC) have been recently shown to be a promising method of altering selectivity. In this work, we present the first multicomponent continuous stationary phase gradient for separations involving both reversed-phase (RP) and strong cation exchange (SCX) mechanisms. These columns are fabricated using a two-step methodology based on controlled rate infusion (CRI). First, destructive CRI creates a gradient of excess silanol groups along a uniform C18 column. Next, these columns are infused with 3-mercaptopropyltrimethoxysilane (MPTMOS), which bonds to the excess silanol groups. The terminal thiols of the MPTMOS ligands are oxidized with H2O2 to create the sulfonate functionality (SO3−) needed for SCX separations. The success of the modification procedure is characterized by thermogravimetric analysis and X-ray photoelectron spectroscopy. The stability of the C18-SO3− gradients were found to have less than 5 % retention loss and the column-to-column reproducibility had a relative standard deviation under 9 %. The peak asymmetry factors for seven biogenic amines were found to be between 1.03 ± 0.04 to 1.30 ± 0.02, which illustrates minimal peak tailing due to poor packing and residual silanol groups. Characterization of the gradient columns using an isocratic mobile phase showed a unique elution order compared to a uniform C18 and SO3− columns. At lower counterion concentrations, more than 48 % of the overall retention on the gradient stationary phase is due to a SCX mechanism. Meanwhile, the RP mechanism was shown to predominate at higher counterion concentrations on the gradient columns (SCX retention contribution less than 40 %). Coupling the stationary phase gradient to a salt gradient in the mobile phase showed that the gradient phase provides a unique, intermediate selectivity to the uniform C18 and SO3− columns. Under an ACN mobile phase gradient, a significant increase (p < 0.003) in the retention times of three biogenic amines (15 – 16 %) was observed when the multicomponent gradient was oriented to have a high SO3− ligand density near the detector. This work serves as a proof-of-concept design for a multicomponent stationary phase gradient to continue fundamental studies into retention and encourage novel applications.

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