Computational synthesis design for controlled degradation and revalorization

Żądło-Dobrowolska, Anna; Molga, Karol; Kolodiazhna, Olga O.; Szymkuć, Sara; Moskal, Martyna; Roszak, Rafał; Grzybowski, Bartosz A.

doi:10.1038/s44160-024-00497-6

Nat. Synth

2024

DOI: 10.1038/s44160-024-00497-6

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Computational synthesis design for controlled degradation and revalorization

Anna Żądło-Dobrowolska,

Karol Molga,

Olga O. Kolodiazhna

et al.

Abstract: Degradation of larger and undesired/harmful molecules into smaller and, ideally, value-added products is one of the important facets of circular chemistry. This task may be cumbersome to chemists who are accustomed to plan syntheses using bond-forming rather than bond-breaking methodologies. This work describes a forward-synthesis algorithm that can guide such degradation-oriented analyses. This algorithm uses a broad knowledge-base of degradative and related reactions and applies them to arbitrary small-molec… Show more

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Cited by 2 publications

References 80 publications

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Integrating machine learning to uncover homogeneous catalytic mechanisms in N‐vinyl‐pyrrolidone synthesis

Zhang,

Wang,

Shen

et al. 2024

AIChE Journal

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Combining machine learning, density functional theory (DFT) calculation, and kinetic modeling offers significant advantages in studying reactions under complex conditions, enabling a detailed exploration of reaction mechanisms. Artificial neural network (ANN) models accurately predict and analyze the impact of reaction conditions, overcoming the limitations of traditional kinetic studies in complex systems. Specifically, the homogeneous catalytic reaction for synthesizing N‐vinylpyrrolidone from pyrrolidone and acetylene, which has stringent requirements, was selected. The ANN model effectively captured nonlinear relationships between residence time, moisture content, reaction temperature, catalyst concentration, reaction pressure, and catalyst preparation temperature. DFT calculations revealed the reaction pathways, leading to the development of a high‐precision predictive model. This approach not only uncovers potential reaction pathways and intermediates in complex reaction systems but also provides a new avenue for optimizing reaction conditions, resulting in more efficient catalyst design and process development in intricate reaction environments.

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Integrating machine learning to uncover homogeneous catalytic mechanisms in N‐vinyl‐pyrrolidone synthesis

Zhang,

Wang,

Shen

et al. 2024

AIChE Journal

View full text Add to dashboard Cite

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Site‐Selective Synthetic Modifications of the Cinchona Alkaloids

Player,

Foley

2024

Asian J Org Chem

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The natural product quinine has been known to humankind for centuries, and in that time has played a pivotal role in the treatment of malaria. Quinine, and the related cinchona alkaloids, have seen widespread contemporary use across chemical and biological disciplines, owing in part to the plethora of functional groups and stereochemical information contained within their scaffold. This review focuses on site‐selective synthetic modifications of the cinchona alkaloids. Our comparative analysis may act as a ‘user manual’ for the selective functionalisation of the cinchona alkaloids, and aims to promote consideration of remarkable and lesser‐understood aspects of cinchona chemistry.

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Computational synthesis design for controlled degradation and revalorization

Cited by 2 publications

References 80 publications

Integrating machine learning to uncover homogeneous catalytic mechanisms in N‐vinyl‐pyrrolidone synthesis

Integrating machine learning to uncover homogeneous catalytic mechanisms in N‐vinyl‐pyrrolidone synthesis

Site‐Selective Synthetic Modifications of the Cinchona Alkaloids

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