Single-Molecule Insights into Retention at a Reversed-Phase Chromatographic Interface

The efficiency of chromatographic separations decreases markedly when peaks exhibit asymmetry (e.g., “peak tailing”). Theoretically, these effects can arise from heterogeneous adsorption kinetics. To investigate the nature and consequences of such heterogeneity, we used a combination of single-molec...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2014-10, Vol.86 (19), p.9451-9458
Main Authors: Mabry, Joshua N, Skaug, Michael J, Schwartz, Daniel K
Format: Article
Language:English
Subjects:
Adsorption
Biochemistry
Boron Compounds - chemistry
Chromatography
Chromatography, Reverse-Phase - standards
Desorption
Fatty Acids - isolation & purification
Fluorescent Dyes - chemistry
Heterogeneity
Hydrophobic and Hydrophilic Interactions
Kinetics
Mathematical models
Methanol
Methyl alcohol
Molecular Dynamics Simulation
Molecular Imaging - methods
Reaction kinetics
Separation
Silicon Dioxide - chemistry
Solvents
Static Electricity
Stochastic models
Surface chemistry
Tailings
Trimethylsilyl Compounds - chemistry
Water
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Summary:The efficiency of chromatographic separations decreases markedly when peaks exhibit asymmetry (e.g., “peak tailing”). Theoretically, these effects can arise from heterogeneous adsorption kinetics. To investigate the nature and consequences of such heterogeneity, we used a combination of single-molecule imaging and reversed-phase liquid chromatography (RPLC). In both single-molecule and macroscopic RPLC experiments, the stationary phase was hydrophobic end-capped (trimethylsilyl-functionalized) silica, which we exposed to different methanol/water solutions (50%–62% methanol), containing a fluorescent fatty acid analyte. Super-resolution maps based on single-molecule observations revealed rare, strong adsorption sites with activity that varied significantly with methanol concentration. The adsorption and desorption kinetics on the strong sites were heterogeneous and positively correlated, suggesting a broad underlying distribution of site binding energies. Adsorption equilibrium on the strong sites was more sensitive to solution conditions than overall retention measured in RPLC experiments, suggesting that the effect of strong sites on the overall adsorption kinetics should change with solution conditions. Interestingly, in RPLC experiments, peak tailing had a nonmonotonic dependence on methanol concentration within the range studied. Using the stochastic model of chromatography, we showed quantitatively that our single-molecule kinetic results were consistent with this macroscopic trend. This approach to identifying and quantifying adsorption sites should be useful for designing better chromatographic separations and for identifying the role of heterogeneous surface chemistry in molecular dynamics.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac5026418