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Hyphenating temperature gradient elution with refractive index detection through temperature-responsive liquid chromatography

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Abstract
Refractive index detection (RID) is attractive because it allows approaching the benefits of universal detection with liquid chromatography, by which ideally standard independent calibration and hence compound independent quantification becomes possible. Nevertheless, the implementation of RID has remained limited as it offers poor detection sensitivity while only being compatible with isocratic mobile phases. The implementation of compositional solvent gradients has remained prohibitively challenging in commercial HPLC-RID systems due to the resulting drastic alterations in refractive index and extreme baseline drift. While the refractive index is also highly dependent on temperature, more leeway appears possible to mitigate the problem, particularly when the used temperature gradients can be limited. Temperature-responsive liquid chromatography (TRLC) allows obtaining isocratic reversed phase type of separations, whereby retention is modulated via temperature changes similar to 15 degrees C-20 degrees C above and below the polymer conversion temperature. Elution profiles, reminiscent of what can be obtained with solvent gradients in conventional RPLC, can then be obtained by enacting downwards temperature gradients on the columns. This work comprises a proof-of-principle to illustrate the possibilities of combining thermal gradient TRLC with RID. The observed baseline drift appeared thereby very minor (<5 nRIU min(-1)), and hence easily controllable. Short chain fatty acids are used as representative compounds to assess this new approach. Overlapping calibration lines are accordingly obtained for all fatty acids between butyric and decanoic acid.
Keywords
Spectroscopy, Environmental Chemistry, Biochemistry, Analytical Chemistry, Refractive index detector, Temperature-responsive liquid chromatography, Temperature gradients, Temperature-responsive polymers, LIGHT-SCATTERING, ORGANIC-ACIDS, HPLC, SUGARS

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Citation

Please use this url to cite or link to this publication:

MLA
Bandini, Elena, et al. “Hyphenating Temperature Gradient Elution with Refractive Index Detection through Temperature-Responsive Liquid Chromatography.” ANALYTICA CHIMICA ACTA, vol. 1231, 2022, doi:10.1016/j.aca.2022.340441.
APA
Bandini, E., Wicht, K., Ampe, A., Baert, M., Eghbali, H., & Lynen, F. (2022). Hyphenating temperature gradient elution with refractive index detection through temperature-responsive liquid chromatography. ANALYTICA CHIMICA ACTA, 1231. https://doi.org/10.1016/j.aca.2022.340441
Chicago author-date
Bandini, Elena, Kristina Wicht, Adriaan Ampe, Mathijs Baert, Hamed Eghbali, and Frederic Lynen. 2022. “Hyphenating Temperature Gradient Elution with Refractive Index Detection through Temperature-Responsive Liquid Chromatography.” ANALYTICA CHIMICA ACTA 1231. https://doi.org/10.1016/j.aca.2022.340441.
Chicago author-date (all authors)
Bandini, Elena, Kristina Wicht, Adriaan Ampe, Mathijs Baert, Hamed Eghbali, and Frederic Lynen. 2022. “Hyphenating Temperature Gradient Elution with Refractive Index Detection through Temperature-Responsive Liquid Chromatography.” ANALYTICA CHIMICA ACTA 1231. doi:10.1016/j.aca.2022.340441.
Vancouver
1.
Bandini E, Wicht K, Ampe A, Baert M, Eghbali H, Lynen F. Hyphenating temperature gradient elution with refractive index detection through temperature-responsive liquid chromatography. ANALYTICA CHIMICA ACTA. 2022;1231.
IEEE
[1]
E. Bandini, K. Wicht, A. Ampe, M. Baert, H. Eghbali, and F. Lynen, “Hyphenating temperature gradient elution with refractive index detection through temperature-responsive liquid chromatography,” ANALYTICA CHIMICA ACTA, vol. 1231, 2022.
@article{8768276,
  abstract     = {{Refractive index detection (RID) is attractive because it allows approaching the benefits of universal detection with liquid chromatography, by which ideally standard independent calibration and hence compound independent quantification becomes possible. Nevertheless, the implementation of RID has remained limited as it offers poor detection sensitivity while only being compatible with isocratic mobile phases. The implementation of compositional solvent gradients has remained prohibitively challenging in commercial HPLC-RID systems due to the resulting drastic alterations in refractive index and extreme baseline drift. While the refractive index is also highly dependent on temperature, more leeway appears possible to mitigate the problem, particularly when the used temperature gradients can be limited. Temperature-responsive liquid chromatography (TRLC) allows obtaining isocratic reversed phase type of separations, whereby retention is modulated via temperature changes similar to 15 degrees C-20 degrees C above and below the polymer conversion temperature. Elution profiles, reminiscent of what can be obtained with solvent gradients in conventional RPLC, can then be obtained by enacting downwards temperature gradients on the columns. This work comprises a proof-of-principle to illustrate the possibilities of combining thermal gradient TRLC with RID. The observed baseline drift appeared thereby very minor (<5 nRIU min(-1)), and hence easily controllable. Short chain fatty acids are used as representative compounds to assess this new approach. Overlapping calibration lines are accordingly obtained for all fatty acids between butyric and decanoic acid.}},
  articleno    = {{340441}},
  author       = {{Bandini, Elena and Wicht, Kristina and Ampe, Adriaan and Baert, Mathijs and Eghbali, Hamed and Lynen, Frederic}},
  issn         = {{0003-2670}},
  journal      = {{ANALYTICA CHIMICA ACTA}},
  keywords     = {{Spectroscopy,Environmental Chemistry,Biochemistry,Analytical Chemistry,Refractive index detector,Temperature-responsive liquid chromatography,Temperature gradients,Temperature-responsive polymers,LIGHT-SCATTERING,ORGANIC-ACIDS,HPLC,SUGARS}},
  language     = {{eng}},
  pages        = {{6}},
  title        = {{Hyphenating temperature gradient elution with refractive index detection through temperature-responsive liquid chromatography}},
  url          = {{http://doi.org/10.1016/j.aca.2022.340441}},
  volume       = {{1231}},
  year         = {{2022}},
}

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