Stochastic machine learning via sigma profiles to build a digital chemical space

Abranches, Dinis O.; Maginn, Edward J.; Colón, Yamil J.

doi:10.1073/pnas.2404676121

Cited by 2 publications

References 32 publications

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Machine Learning Optimization of Non-Kasha Behavior and of Transient Dynamics in Model Retinal Isomerization

Singh,

Chuang,

Brumer

2024

J. Phys. Chem. Lett.

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Designing a model of retinal isomerization in rhodopsin, the first step in vision, that accounts for both experimental transient and stationary state observables is challenging. Here, multiobjective Bayesian optimization is employed to refine the parameters of a minimal two-state-two-mode (TM) model describing the photoisomerization of retinal in rhodopsin. The optimized retinal model predicts excitation wavelengthdependent fluorescence spectra that closely align with experimentally observed non-Kasha behavior in the nonequilibrium steady state. Further, adjustments to the potential energy surface within the TM model reduce the discrepancies across the time domain. Overall, agreement with experimental data is excellent.

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Machine Learning Optimization of Non-Kasha Behavior and of Transient Dynamics in Model Retinal Isomerization

Singh,

Chuang,

Brumer

2024

J. Phys. Chem. Lett.

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Enhanced Prediction of Molecular Properties Using Transfer Learning on Sigma Profiles

Yin,

Gao,

et al. 2024

Preprint

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The performance of machine learning techniques for the prediction of a wide range of molecular properties has seen rapid improvements in recent years due to developments in both molecular representations and deep learning modeling techniques. Sigma profiles, which are a computational descriptor representing the surface charge distribution of molecules, have shown promise as a molecular representation to support robust property prediction. Meanwhile, large-scale pretrained deep learning models based directly on molecular structure inputs, such as Uni-Mol, have demonstrated strong performance as general-purpose molecular representation learners. In this study, we seek to enhance the prediction of molecular properties by integrating information from sigma profiles with these advanced deep learning techniques. Our methodology involves fine-tuning the Uni-Mol model to accurately predict sigma profiles, which capture detailed molecular structural information important for determining molecular interactions. We then utilize transfer learning to apply the learned weights to predict specific molecular properties, replacing the final output layer to adapt to each new task. The results demonstrate improvements in predictive accuracy across various datasets, showcasing the effectiveness of combining sigma profiles with state-of-the-art machine learning models and demonstrating a path forward for leveraging theory-driven descriptor development to enhance large-scale data-driven molecular property modeling.

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Stochastic machine learning via sigma profiles to build a digital chemical space

Cited by 2 publications

References 32 publications

Machine Learning Optimization of Non-Kasha Behavior and of Transient Dynamics in Model Retinal Isomerization

Machine Learning Optimization of Non-Kasha Behavior and of Transient Dynamics in Model Retinal Isomerization

Enhanced Prediction of Molecular Properties Using Transfer Learning on Sigma Profiles

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