Learning Matter: Materials Design with Machine Learning and Atomistic Simulations

Axelrod, Simon; Schwalbe-Koda, Daniel; Mohapatra, Somesh; Damewood, James; Greenman, Kevin P.; Gómez‐Bombarelli, Rafael

doi:10.1021/accountsmr.1c00238

Cited by 51 publications

(45 citation statements)

References 57 publications

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“…Standard quantum chemistry approaches are rather slow. To address this and the above issues, we develop an ISC workflow based on ML potentials 30 that are trained on multireference SF-TDDFT data.…”

Section: ■ Theory and Methodsmentioning

confidence: 99%

Thermal Half-Lives of Azobenzene Derivatives: Virtual Screening Based on Intersystem Crossing Using a Machine Learning Potential

2023

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Molecular photoswitches are the foundation of light-activated drugs. A key photoswitch is azobenzene, which exhibits trans−cis isomerism in response to light. The thermal halflife of the cis isomer is of crucial importance, since it controls the duration of the light-induced biological effect. Here we introduce a computational tool for predicting the thermal half-lives of azobenzene derivatives. Our automated approach uses a fast and accurate machine learning potential trained on quantum chemistry data. Building on well-established earlier evidence, we argue that thermal isomerization proceeds through rotation mediated by intersystem crossing, and incorporate this mechanism into our automated workflow. We use our approach to predict the thermal half-lives of 19,000 azobenzene derivatives. We explore trends and trade-offs between barriers and absorption wavelengths, and open-source our data and software to accelerate research in photopharmacology.

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Section: ■ Theory and Methodsmentioning

confidence: 99%

Thermal Half-Lives of Azobenzene Derivatives: Virtual Screening Based on Intersystem Crossing Using a Machine Learning Potential

2023

Self Cite

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“…A vertex-and edge-labeled graph (vertices = atoms, edges = bonds, vertex label = element, edge label = bond order) is a fundamental representation of the concept of a small molecule 2 . However, because classical machine learning algorithms operate in a Euclidean vector space, much research is devoted to the design of fixed-size, information-rich vector representations of molecules that encode their salient features [66,[70][71][72]. Many molecular fingerprinting methods [72] extract topological features from the molecular graph [72] to produce a "bag of fragments" bit vector representation of the molecule [73].…”

Section: Representing Molecules For Supervised Machine Learning Tasksmentioning

confidence: 99%

Classifying the toxicity of pesticides to honey bees via support vector machines with random walk graph kernels

Yang

Henle

Fern

et al. 2022

The Journal of Chemical Physics

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Pesticides benefit agriculture by increasing crop yield, quality, and security. However, pesticides may inadvertently harm bees, which are valuable as pollinators. Thus, candidate pesticides in development pipelines must be assessed for toxicity to bees. Leveraging a dataset of 382 molecules with toxicity labels from honey bee exposure experiments, we train a support vector machine (SVM) to predict the toxicity of pesticides to honey bees. We compare two representations of the pesticide molecules: (i) a random walk feature vector listing counts of length- L walks on the molecular graph with each vertex- and edge-label sequence and (ii) the Molecular ACCess System (MACCS) structural key fingerprint (FP), a bit vector indicating the presence/absence of a list of pre-defined subgraph patterns in the molecular graph. We explicitly construct the MACCS FPs but rely on the fixed-length- L random walk graph kernel (RWGK) in place of the dot product for the random walk representation. The L-RWGK-SVM achieves an accuracy, precision, recall, and F1 score (mean over 2000 runs) of 0.81, 0.68, 0.71, and 0.69, respectively, on the test data set—with L = 4 being the mode optimal walk length. The MACCS-FP-SVM performs on par/marginally better than the L-RWGK-SVM, lends more interpretability, but varies more in performance. We interpret the MACCS-FP-SVM by illuminating which subgraph patterns in the molecules tend to strongly push them toward the toxic/non-toxic side of the separating hyperplane.

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“…In addition to the shortcomings described above, standard quantum chemistry approaches are also rather slow. To address this and the above issues, we develop an ISC workflow based on ML potentials [22] that are trained on multi-reference SF-TDDFT data.…”

Section: Computational Workflowmentioning

confidence: 99%

Thermal half-lives of azobenzene derivatives: virtual screening based on intersystem crossing using a machine learning potential

Axelrod¹,

Shakhnovich²,

Gómez‐Bombarelli³

2022

Preprint

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Molecular photoswitches are the foundation of light-activated drugs. A key photoswitch is azobenzene, which exhibits trans-cis isomerism in response to light. The thermal half-life of the cis isomer is of crucial importance, since it controls the duration of the light-induced biological effect. Here we introduce a computational tool for predicting the thermal half-lives of azobenzene derivatives. Our automated approach uses a fast and accurate machine learning potential trained on quantum chemistry data. Building on well-established earlier evidence, we argue that thermal isomerization proceeds through rotation mediated by intersystem crossing, and incorporate this mechanism into our automated workflow. We use our approach to predict the thermal half-lives of 19,000 azobenzene derivatives. We explore trends and tradeoffs between barriers and absorption wavelengths, and open-source our data and software to accelerate research in photopharmacology.

show abstract

Learning Matter: Materials Design with Machine Learning and Atomistic Simulations

Cited by 51 publications

References 57 publications

Thermal Half-Lives of Azobenzene Derivatives: Virtual Screening Based on Intersystem Crossing Using a Machine Learning Potential

Thermal Half-Lives of Azobenzene Derivatives: Virtual Screening Based on Intersystem Crossing Using a Machine Learning Potential

Classifying the toxicity of pesticides to honey bees via support vector machines with random walk graph kernels

Thermal half-lives of azobenzene derivatives: virtual screening based on intersystem crossing using a machine learning potential

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