Quantitative Structure–Retention Relationship Modeling of Morphine and Its Derivatives on OV-1 Column in Gas–Liquid Chromatography Using Genetic Algorithm

Quantitative Structure–Retention Relationship Modeling of Morphine and Its Derivatives on OV-1 Column in Gas–Liquid Chromatography Using Genetic Algorithm

In this paper, a back propagation artificial neural network (BP-ANN) was used for quantitative structure–retention relationship (QSRR) modeling of retention time ( t R ) of 57 morphine and its derivatives. The molecular descriptors were calculated for each compound. By applying a genetic algorithm,...

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Veröffentlicht in:Chromatographia 2017-04, Vol.80 (4), p.629-636
Hauptverfasser: Bahmani, Asrin, Saaidpour, Saadi, Rostami, Amin
Format: Artikel
Sprache:eng
Schlagworte:
Analytical Chemistry
Artificial neural networks
Back propagation networks
Chemistry
Chemistry and Materials Science
Chromatography
Column chromatography
Columnar structure
Correlation coefficients
Genetic algorithms
Laboratory Medicine
Liquid chromatography
Modelling
Molecular structure
Morphine
Original
Pharmacy
Proteomics
Root-mean-square errors
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Zusammenfassung:In this paper, a back propagation artificial neural network (BP-ANN) was used for quantitative structure–retention relationship (QSRR) modeling of retention time ( t R ) of 57 morphine and its derivatives. The molecular descriptors were calculated for each compound. By applying a genetic algorithm, the most relevant descriptors were selected to build the QSRR model. The selected descriptors were: Hosoya Index, kappa1, and most negative potential. The prediction results from the BP-ANN were in good agreement with the experimental values. The optimal QSRR model was developed based on a 3-3-1 artificial neural network architecture using molecular descriptors calculated from molecular structure alone. The root-mean-square error (RMSE) and squared correlation coefficient ( R 2 ) for the ANN model were 0.3996 and 0.9559 for the training set (42 molecules) and 0.6052 and 0.9540 for the prediction set (15 molecules), respectively.
ISSN:0009-5893
1612-1112
DOI:10.1007/s10337-017-3273-7