Chromatography Modeling Software Applicability for Non-Conventional Columns: a Case Study of Calixarene- and Resorcinarene-Bonded Stationary Phases

In this study a systematic evaluation of the applicability of DryLab for calixarene- and resorcinarene-bonded stationary phases and some other relatively new reversed-phase columns with the presence of conventional alkyl-bonded phases was carried out. Calixarene- and resorcinarene-bonded stationary phases belong to the reversed-phase materials. However, depending on the analytes, they show some additional interactions, since their steric, polar and ionic properties are different compared to those of conventional alkyl-bonded phases. Three different mixtures of model analytes, consisting of alkyl substituted benzene derivatives, 4-hydroxybenzoic acid esters and polycyclic aromatic hydrocarbons, were used to verify the accuracy of DryLab prediction of retention times and to compare the results of 20 different liquid chromatographic phases. The type and the content of the organic modifier as well as the temperature and the gradient time were systematically changed using same conditions for all stationary phases. The results showed that the prediction on the calixarene- and resorcinarene-bonded stationary phases as well as on other reversed-phase columns is highly accurate in both isocratic and gradient modes. The predictions and real experiments were highly correlated with an average absolute error (∆t _R) of 0.027 min (<2 s) and an average percent absolute error (%∆t _R) of 0.38 on the calixarene- and resorcinarene-bonded stationary phases, and ∆t _R of 0.04 min (<3 s); %∆t _R of 0.51 on the other reversed-phase columns in this study. As a result, DryLab could be applied with very accurate predictions in method development using calixarene- and resorcinarene-bonded stationary phases, which were used as an example for “new” stationary phase materials.

     

Evaluation of the Chromatographic Performance of Conventional, Polar-Endcapped and Calixarene-Bonded Stationary Phases for the Separation of Water-Soluble Vitamins

The performance of four different reversed-phase columns which included a conventional C₁₈ phase, a C₁₈ polar-endcapped phase, an ether-linked phenyl polar-endcapped phase and a calixarene-bonded phase has been systematically compared for the separation of mixture of some water-soluble vitamins containing basic, neutral and acidic compounds of different polarities, as well as different functional groups at three pH levels and different proportions of buffer/methanol. The characteristics of water-soluble vitamins make this combination of compounds very useful as a test mixture to check column performance with real samples. Due to the physical and chemical differences between these compounds, the type of chosen column has a significant influence on the chromatographic behavior. Results of this comparison show that the C₁₈ polar-endcapped phase was the most suitable for the separation of this group of vitamins. The presence of a polar group as an endcapping agent does not seem to influence the overall hydrophobic nature of the polar-endcapped stationary phases. At the same time, these phases displayed enhanced hydrogen bonding and silanol activity.     

Chromatography Modeling Software Applicability for Non-Conventional Columns: a Case Study of Calixarene- and Resorcinarene-Bonded Stationary Phases

In this study a systematic evaluation of the applicability of DryLab for calixarene- and resorcinarene-bonded stationary phases and some other relatively new reversed-phase columns with the presence of conventional alkyl-bonded phases was carried out. Calixarene- and resorcinarene-bonded stationary phases belong to the reversed-phase materials. However, depending on the analytes, they show some additional interactions, since their steric, polar and ionic properties are different compared to those of conventional alkyl-bonded phases. Three different mixtures of model analytes, consisting of alkyl substituted benzene derivatives, 4-hydroxybenzoic acid esters and polycyclic aromatic hydrocarbons, were used to verify the accuracy of DryLab prediction of retention times and to compare the results of 20 different liquid chromatographic phases. The type and the content of the organic modifier as well as the temperature and the gradient time were systematically changed using same conditions for all stationary phases. The results showed that the prediction on the calixarene- and resorcinarene-bonded stationary phases as well as on other reversed-phase columns is highly accurate in both isocratic and gradient modes. The predictions and real experiments were highly correlated with an average absolute error (?t _R) of 0.027 min (<2 s) and an average percent absolute error (%?t _R) of 0.38 on the calixarene- and resorcinarene-bonded stationary phases, and ?t _R of 0.04 min (<3 s); %?t _R of 0.51 on the other reversed-phase columns in this study. As a result, DryLab could be applied with very accurate predictions in method development using calixarene- and resorcinarene-bonded stationary phases, which were used as an example for “new” stationary phase materials.