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Abstract
Essential oils contain a variety of volatile metabolites, and are expected to be utilized in wide fields such as antimicrobials, insect repellents and herbicides. However, it is difficult to foresee the effect of mixing the oils because hundreds of compounds can be involved in synergistic and antagonistic interactions. For efficient formula optimization, we have developed and evaluated a machine learning method to classify antibacterial interactions between the oils. Cross-validation showed that graph embedding improved areas under the ROC curves for synergistic-versus-rest classification. Furthermore, antibacterial assay against Staphylococcus aureus revealed that oregano–ajowan, lemongrass–hiba, cinnamon–lemongrass and ajowan–ginger combinations exhibited synergistic interaction as predicted. These results indicate that graph embedding approach is useful for predicting synergistic interaction between antibacterial essential oils.
Supplementary materials
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Table S1.
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Antibacetrial interaction reported on Staphylococcus aureus.
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Table S2.
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Chemical composition of EOs in literature.
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Table S3.
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AUC and partial AUCs obtained by ten-fold cross-validation for four binary operators.
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Table S4.
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Chemical composition data provided by EO product suppliers.
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Table S5.
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Chemical composition of the selected EOs analyzed by GC/MS.
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Table S6.
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Probability output of the synergistic and antagonistic interactions obtained by the proposed approach.
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