Abstract
Prediction of the retention time from the molecular structure using quantitative structure-retention relationships is a powerful tool for the development of methods in reversed-phase HPLC. However, its fundamental limitation lies in the fact that low error in the prediction of the retention time does not necessarily guarantee a prediction of the elution order. Here, we propose a new method for the prediction of the elution order from quantitative structure-retention relationships using multi-objective optimization. Two case studies were evaluated: (i) separation of organic molecules in a Supelcosil LC-18 column, and (ii) separation of peptides in seven columns under varying conditions. Results have shown that, when compared to predictions based on the conventional model, the relative root mean square error of the elution order decreases by 48.84%, while the relative root mean square error of the retention time increases by 4.22% on average across both case studies. The predictive ability in terms of both retention time and elution order and the corresponding applicability domains were defined. The models were deemed stable and robust with few to no structural outliers.
Highlights
High-performance liquid chromatography in the reverse-phase separation mode (RP-HPLC), accounts for more than 90% of separations in modern analytical laboratories [1]
A few columns stand out, especially the Discovery RP Amide C16, in all the combinations of gradients and column temperatures, which exhibited that errors in the elution order are up to 70% even after multi-objective optimization coefficients determined through (MOO)
Performance all the columns in CS2 involving the separation of absence of isomeric peptides, so the models have not accounted for the proximity effects of two synthetic peptides in terms of elution order predictions was ranked using sum of ranking differences (SRD) analysis
Summary
High-performance liquid chromatography in the reverse-phase separation mode (RP-HPLC), accounts for more than 90% of separations in modern analytical laboratories [1]. QSRRs can be useful in a variety of applications, such as identification of the most useful structural descriptors that describe the retention mechanism, prediction of retention time of new analytes, and the identification of unknown analytes. It can be used for the quantitative comparison of separation properties of different chromatographic columns; for evaluation of physical properties, such as lipophilicity or dissociation constants; as well as estimation of relative bioactivities of xenobiotics [2]. B. The following three cases in yield identical retention5.1 time but different elution order analyte B.
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