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Optibrium Announces Free Models to Predict Toxicity of Compounds

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Optibrium™, has announced the availability of a range of models to help predict the toxicity of potential new compounds. Optibrium has generated a range of Quantitative Structure Activity Relationship (QSAR) models of key toxicity endpoints, based on data made available by the US Environmental Protection Agency (EPA) as part of its Toxicity Evaluation Software Toolkit (T.E.S.T.).

The toxicity prediction models were built with the Auto-Modeller™ module of the newly launched StarDrop™ 5 and are available to all StarDrop users free-of-charge. To find out more and download the models please visit Optibrium’s on-line community at http://www.optibrium.com/community.

Whether compounds are intended as drugs, cosmetics, agrochemicals or for other industrial applications, it is essential to understand their potential to cause toxic effects. Understanding this can allow scientists to prioritize chemical structures for further research or identify the most appropriate downstream experiments to confirm their safety.

However, the ability to predict toxicities in compounds can be extremely challenging. Models have a high degree of uncertainty in the predictions they make due to the complexity and variety of chemical and biological mechanisms that lead to toxicities.

StarDrop, from Optibrium, is an interactive platform that guides scientists to make decisions on the design and selection of high quality compounds with the aim of achieving an optimal balance of properties.

StarDrop provides an ideal environment for application of toxicity models to the selection of compounds. Its probabilistic scoring algorithm allows predictive models of toxicity to be used, while explicitly taking into consideration the uncertainty in each prediction. This ensures that uncertain predictions are not given undue weight, relative to other data, when prioritizing compounds that are more likely to have an appropriate balance of properties.

As a result, compounds which are more likely to be toxic are efficiently identified, improving lead optimization. The unique Glowing Molecule™ feature within StarDrop offers an innovative visualization that highlights regions of a compound with a significant influence on a predicted property. As a result, this provides a link between the predicted toxicity and the chemical mechanism and guides users in the redesign of compounds with improved safety.

“These predictive toxicity models complement the range of properties that can already be predicted with StarDrop’s ADME QSAR module. As they’re based on public-domain data sets, we’re pleased to offer them free-of-charge to all of our users.” comments Dr. Matthew Segall, CEO of Optibrium.

Segall continued, “Many of the toxicity prediction models developed with the use of StarDrop are particularly relevant to potential environmental pollutants. This illustrates the usability of StarDrop not just for drug discovery applications, but for industrial, agrochemical or cosmetic applications.”

The toxicity prediction models conform to the Organisation for Economic Cooperation and Development (OECD) principles for validation of QSAR models for regulatory purposes and have also been found to perform equivalently or better than the EPA T.E.S.T. models on the same validation sets.

All models were built automatically with StarDrop’s Auto-modeller module, illustrating that the Auto-Modeller is capable of building models that compare favourably with those created with more ‘manual’ methods.