Extended Activity Cliffs-Driven Approaches on Data Splitting for the Study of Bioactivity Machine Learning Predictions.

Journal: Molecular informatics

PMID: 39558572

Abstract

The presence of Activity Cliffs (ACs) has been known to represent a challenge for QSAR modeling. With its high data dependency, Machine Learning QSAR models will be directly influenced by the activity landscape. We propose several extended similarity and extended SALI methods to study the implications of ACs distribution on the training and test sets on the model's errors. Ununiform ACs and chemical space distribution tend to lead to worse models than the proposed uniform methods. ML modeling on AC-rich sets needs to be analyzed case-by-case. Proposed methods can be used as a tool to study the datasets, but as far as generalization, random splitting was the better-performing data splitting alternative overall.

Authors

Kenneth López-Pérez

Department of Chemistry and Quantum Theory Project, University of Florida, Gainesville, Florida 32611, USA.
Ramón Alain Miranda-Quintana

Department of Chemistry and Quantum Theory Project, University of Florida, Gainesville, FL, 32603, USA.

Keywords

Machine Learning Quantitative Structure-Activity Relationship

External Resources

View on PubMed Access via DOI PubMed (39558572)

Extended Activity Cliffs-Driven Approaches on Data Splitting for the Study of Bioactivity Machine Learning Predictions.

Abstract

Authors

Keywords

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