Capacitively coupled contactless conductivity detection to account for system-induced gradient deformation in liquid chromatography

Leon E. Niezen, Tijmen S. Bos, Peter J. Schoenmakers, Govert W. Somsen, Bob W.J. Pirok*

*Corresponding author for this work

Research output: Contribution to JournalArticleAcademicpeer-review

Abstract

The time required for method development in gradient-elution liquid chromatography (LC) may be reduced by using an empirical modelling approach to describe and predict analyte retention and peak width. However, prediction accuracy is impaired by system-induced gradient deformation, which can be especially prominent for steep gradients. As the deformation is unique to each LC instrument, it needs to be corrected for if retention modelling for optimization and method transfer is to become generally applicable. Such a correction requires knowledge of the actual gradient profile. The latter has been measured using capacitively coupled “contactless” conductivity detection (C4D), featuring a low detection volume (approximately 0.05 μL) and compatibility with very high pressures (80 MPa or more). Several different solvent gradients, from water to acetonitrile, water to methanol, and acetonitrile to tetrahydrofuran, could be measured directly without the addition of a tracer component to the mobile phase, exemplifying the universal nature of the approach. Gradient profiles were found to be unique for each solvent combination, flowrate, and gradient duration. The profiles could be described by convoluting the programmed gradient with a weighted sum of two distribution functions. Knowledge of the exact profiles was used to improve the inter-system transferability of retention models for toluene, anthracene, phenol, emodin, sudan-I and several polystyrene standards.

Original languageEnglish
Article number341466
Pages (from-to)1-12
Number of pages12
JournalAnalytica Chimica Acta
Volume1271
Early online date1 Jun 2023
DOIs
Publication statusPublished - 29 Aug 2023

Bibliographical note

Funding Information:
LN and TB acknowledge the UNMATCHED project, which is supported by BASF, DSM and Nouryon and receives funding from the Dutch Research Council (NWO) in the framework of the Innovation Fund for Chemistry (CHIPP Project 731.017.303) and from the Ministry of Economic Affairs in the framework of the “TKI-toeslagregeling”. BP acknowledges the Agilent UR grant #4354. This work was performed in the context of the Chemometrics and Advanced Separations Team (CAST) within the Centre for Analytical Sciences Amsterdam (CASA). The valuable contributions of the CAST members are gratefully acknowledged.

Funding Information:
LN and TB acknowledge the UNMATCHED project, which is supported by BASF , DSM and Nouryon and receives funding from the Dutch Research Council (NWO) in the framework of the Innovation Fund for Chemistry ( CHIPP Project 731.017.303 ) and from the Ministry of Economic Affairs in the framework of the “TKI-toeslagregeling”. BP acknowledges the Agilent UR grant #4354 .

Publisher Copyright:
© 2023 The Authors

Keywords

  • Contactless conductivity detector
  • Deconvolution
  • Gradient deformation
  • Gradient-elution liquid chromatography
  • Instrument-independent retention parameters
  • Method transfer
  • Response functions

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