A Compact Instrument for Temperature-Programming-Assisted Capillary–Nanoliquid Chromatography

The miniaturization of liquid chromatography (LC) columns to capillary and nanoscales allows temperature programming to be an effective alternative to solvent gradients for modulating eluotropic strength. This approach simplifies instrument design and operation, as a single pump can suffice to achie...

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Bibliographic Details
Published in:Separations 2024-12, Vol.12 (1), p.5
Main Authors: Marins, Lincon Coutinho, Monteiro, Alessandra Maffei, Leal, Vivane Lopes, Medina, Deyber Arley Vargas, Cardenas, Edwin Martin, Lanças, Fernando Mauro
Format: Article
Language:English
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Summary:The miniaturization of liquid chromatography (LC) columns to capillary and nanoscales allows temperature programming to be an effective alternative to solvent gradients for modulating eluotropic strength. This approach simplifies instrument design and operation, as a single pump can suffice to achieve efficient separations. This study presents the development and application of a compact, lab-built high-pressure system for temperature-programmed capillary and nanoLC separations. The instrument includes a high-pressure capillary–nanoflow syringe pump, a time-based nanoliter injection system, a programmable capillary column oven for controlled temperature gradients, and a UV-Vis detection system with a custom nanoliter-scale detection cell. Each system component was designed and built in-house, with rigorous calibration to ensure accuracy and operational reliability. Experimental data confirm the system’s capability to deliver precise, reproducible temperature, and flow rates. Functionality was validated through temperature-programmed separations on packed and open tubular capillary columns. The results demonstrated that the developed instrument offers enhanced separation efficiency and reduced analysis time compared to isothermal methods, underscoring its potential for advanced applications in miniaturized liquid chromatography.
ISSN:2297-8739
2297-8739
DOI:10.3390/separations12010005