Comparison of migration modeling in micellar electrokinetic chromatography by linear regression and by use of an artificial neural network

The concentrations of modifier (methanol or acetonitrile) and surfactant (sodium dodecyl sulfate, SDS) in the running buffer are important factors influencing the mobility of analytes in micellar electrokinetic chromatography (MEKC). Response surfaces of the effective mobility can be used to predict...

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Bibliographic Details
Published in:Chromatographia 2000, Vol.52 (9-10), p.607-613
Main Authors: Metting, H. J, van Zomeren, P. V, van der Ley, C. P, Coenegracht, P. M. J, de Jong, G. J
Format: Article
Language:English
Subjects:
Acetonitrile
Analysis
Analytical chemistry
Artificial neural networks
Back propagation networks
Biological and medical sciences
Buffers
Chemistry
Chromatographic methods and physical methods associated with chromatography
Chromatography
Cocaine
Configurations
Electrokinetics
Exact sciences and technology
General pharmacology
Impurities
linear models
Medical sciences
methanol
micellar electrokinetic capillary chromatography
Modelling
Neural networks
neurons
Other chromatographic methods
Performance prediction
Pharmacology. Drug treatments
Polynomials
prediction
Regression analysis
Regression models
Sodium dodecyl sulfate
surfactants
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Summary:The concentrations of modifier (methanol or acetonitrile) and surfactant (sodium dodecyl sulfate, SDS) in the running buffer are important factors influencing the mobility of analytes in micellar electrokinetic chromatography (MEKC). Response surfaces of the effective mobility can be used to predict mobility as a function of the buffer composition.This paper describes the modeling, by multiple linear regression and by use of a back-propagation neural network, of the response surfaces of the effective mobility of cocaine and related compounds, of fluvoxamine and its possible impurities, and of a mixture of alkylphenones. Special attention has been paid to selection of the proper order of the regression models, to selection of the proper network configuration, and to the predictive quality of the models. The regression models were selected by backward elimination of non-significant terms starting with a full second-order polynomial model. The proper network configuration was selected by finding the optimum number of hidden neurons by lateral inhibition and subsequent determination of the optimum number of training cycles by a cross-validation method.On the basis of the multiple determination coefficient,R ², the descriptive performances of the neural network and the regression models are almost the same. However, the predictive performance of the regression models and the neural network models are approximately equal for migration in MEKC. The relative prediction error of the effective mobility is ca 2.5% for cocaine and related compounds, 1 – 7% for the alkylphenones, and 1.5 – 2.2% for fluvoxamine and its possible impurities; this is approximately the same order of magnitude, or slightly higher, than the relative standard deviation of the replicate measurements.
ISSN:0009-5893
1612-1112
DOI:10.1007/BF02789760