Jon W. Ball scite author profile

Quantitative structure‐toxicity models were developed that directly link the molecular structures of a set of 50 alkylated and/or halogenated phenols with their polar narcosis toxicity, expressed as the negative logarithm of the IGC50 (50% growth inhibitory concentration) value in millimoles per liter. Regression analysis and fully connected, feed‐forward neural networks were used to develop the models. Two neural network training algorithms (back‐propagation and a quasi‐Newton method) were employed. The best model was a quasi‐Newton neural network that had a root‐mean‐square error of 0.070 log units for the 45 training set phenols and 0.069 log units for the five cross‐validation set phenols.

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Quantitative Structure-Activity Relationships for Toxicity of Phenols Using Regression Analysis and Computational Neural Networks

Ball

Dixon

et al. 1994

Environ Toxicol Chem

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Quantitative structure-toxicity models were developed that directly link the molecular structures of a set of 50 alkylated and/or halogenated phenols with their polar narcosis toxicity, expressed as the negative logarithm of the IGCSO (50Vo growth inhibitory concentration) value in millimoles per liter. Regression analysis and fully connected, feed-forward neural networks were used to develop the models. Two neural network training algorithms (back-propagation and a quasi-Newton method) were employed. The best model was a quasi-Newton neural network that had a root-mean-square error of 0.070 log units for the 45 training set phenols and 0.069 log units for the five cross-validation set phenols.

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Carbon-13 nuclear magnetic resonance spectrum simulation

Jurs¹,

Ball²,

Anker³

et al. 1992

J. Chem. Inf. Comput. Sci.

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Automated selection of regression models using neural networks for carbon-13 NMR spectral predictions

Ball¹,

Jurs²

1993

Anal. Chem.

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Simulation of polysaccharide carbon-13 nuclear magnetic resonance spectra using regression analysis and neural networks

Ball¹,

Jurs²

1993

Anal. Chem.

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Jon W. Ball

Quantitative structure‐activity relationships for toxicity of phenols using regression analysis and computational neural networks

Quantitative Structure-Activity Relationships for Toxicity of Phenols Using Regression Analysis and Computational Neural Networks

Carbon-13 nuclear magnetic resonance spectrum simulation

Automated selection of regression models using neural networks for carbon-13 NMR spectral predictions

Simulation of polysaccharide carbon-13 nuclear magnetic resonance spectra using regression analysis and neural networks

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