3 research outputs found
Using Artificial Intelligence to Formulate New Deep Eutectic Solvents
The advances in Artificial Intelligence (AI) in the past two decades have enabled algorithms to perform daily human-like tasks such as driving cars, playing complex games, composing classical music, and even generating realistic images by using text as the input parameter. These achievements were accomplished with the implementation of Deep Neural Network (DNN) architecture along with the use of large databases, as well as the increase in computing power. This strategy has also shown promise in several sub-fields of natural sciences such as chemistry, biology, and physics through speech recognition, data analysis, and computer vision. More specifically, in chemistry, deep learning has been used to predict the properties of molecules and predict chemical reactions. To predict the properties of molecules and chemical reactions, a large database of compounds or molecules, such as Deep Eutectic Solvents (DES), must be written in a simplified text such as a Simplified Molecular Input Line Entry System (SMILES). A SMILES database is easily understood by computers, and it translates a chemical structure into a string. With the use of the SMILES database, we were able to train a model with Natural Deep Eutectic Solvents, so the AI could eventually determine if the compounds inputted with SMILES were unstable or stable
Predicting Antioxidant Synergism via Artificial Intelligence and Benchtop Data
Lipid oxidation is a major issue
affecting products containing
unsaturated fatty acids as ingredients or components, leading to the
formation of low molecular weight species with diverse functional
groups that impart off-odors and off-flavors. Aiming to control this
process, antioxidants are commonly added to these products, often
deployed as combinations of two or more compounds, a strategy that
allows for lowering the amount used while boosting the total antioxidant
capacity of the formulation. While this approach allows for minimizing
the potential organoleptic and toxic effects of these compounds, predicting
how these mixtures of antioxidants will behave has traditionally been
one of the most challenging tasks, often leading to simple additive,
antagonistic, or synergistic effects. Approaches to understanding
these interactions have been predominantly empirically driven but
thus far, inefficient and unable to account for the complexity and
multifaceted nature of antioxidant responses. To address this current
gap in knowledge, we describe the use of an artificial intelligence
model based on deep learning architecture to predict the type of interaction
(synergistic, additive, and antagonistic) of antioxidant combinations.
Here, each mixture was associated with a combination index value (CI)
and used as input for our model, which was challenged against a test
(n = 140) data set. Despite the encouraging preliminary
results, this algorithm failed to provide accurate predictions of
oxidation experiments performed in-house using binary mixtures of
phenolic antioxidants and a lard sample. To overcome this problem,
the AI algorithm was then enhanced with various amounts of experimental
data (antioxidant power data assessed by the TBARS assay), demonstrating
the importance of having chemically relevant experimental data to
enhance the model’s performance and provide suitable predictions
with statistical relevance. We believe the proposed method could be
used as an auxiliary tool in benchmark analysis routines, offering
a novel strategy to enable broader and more rational predictions related
to the behavior of antioxidant mixtures
Predicting Antioxidant Synergism via Artificial Intelligence and Benchtop Data
Lipid oxidation is a major issue
affecting products containing
unsaturated fatty acids as ingredients or components, leading to the
formation of low molecular weight species with diverse functional
groups that impart off-odors and off-flavors. Aiming to control this
process, antioxidants are commonly added to these products, often
deployed as combinations of two or more compounds, a strategy that
allows for lowering the amount used while boosting the total antioxidant
capacity of the formulation. While this approach allows for minimizing
the potential organoleptic and toxic effects of these compounds, predicting
how these mixtures of antioxidants will behave has traditionally been
one of the most challenging tasks, often leading to simple additive,
antagonistic, or synergistic effects. Approaches to understanding
these interactions have been predominantly empirically driven but
thus far, inefficient and unable to account for the complexity and
multifaceted nature of antioxidant responses. To address this current
gap in knowledge, we describe the use of an artificial intelligence
model based on deep learning architecture to predict the type of interaction
(synergistic, additive, and antagonistic) of antioxidant combinations.
Here, each mixture was associated with a combination index value (CI)
and used as input for our model, which was challenged against a test
(n = 140) data set. Despite the encouraging preliminary
results, this algorithm failed to provide accurate predictions of
oxidation experiments performed in-house using binary mixtures of
phenolic antioxidants and a lard sample. To overcome this problem,
the AI algorithm was then enhanced with various amounts of experimental
data (antioxidant power data assessed by the TBARS assay), demonstrating
the importance of having chemically relevant experimental data to
enhance the model’s performance and provide suitable predictions
with statistical relevance. We believe the proposed method could be
used as an auxiliary tool in benchmark analysis routines, offering
a novel strategy to enable broader and more rational predictions related
to the behavior of antioxidant mixtures