Reinforcing the Supply Chain of Umifenovir and Other Antiviral Drugs with Retrosynthetic Software

Lin, Yong; Zirong, Zhang; Mahjour, Babak; Wang, Di; Zhang, Rui; Eunjae, Shim; Andrew, M.; Yuning, Shen; Nadia, Brugger; Turnbull, Rachel; Sarah, Trice; Shashi, Jasty; Cernak, Tim

doi:10.21203/rs.3.rs-820369/v1

Cited by 3 publications

(5 citation statements)

References 17 publications

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“…These results clearly show that retrosynthesis knowledge effectively contributes to retrosynthetic analyses using ReTReK. However, the experimental validations 56 with targets that chemists are interested in and blind assessments 9 by trained chemists are not performed in this study; thus we plan to perform these validations to evaluate the performance of ReTReK on actual chemical synthesis in future work. Considering these evaluations and demonstrations, the ReTReK framework with integrated retrosynthesis knowledge has the potential to further improve the performance of datadriven CASP applications.…”

Section: ■ Results and Discussionmentioning

confidence: 96%

AI-Driven Synthetic Route Design Incorporated with Retrosynthesis Knowledge

Ishida

Terayama

Kojima

et al. 2022

J. Chem. Inf. Model.

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Computer-aided synthesis planning (CASP) aims to assist chemists in performing retrosynthetic analysis for which they utilize their experiments, intuition, and knowledge. Recent breakthroughs in machine learning (ML) techniques, including deep neural networks, have significantly improved data-driven synthetic route designs without human intervention. However, learning chemical knowledge by ML for practical synthesis planning has not yet been adequately achieved and remains a challenging problem. In this study, we developed a data-driven CASP application integrated with various portions of retrosynthesis knowledge called “ReTReK” that introduces the knowledge as adjustable parameters into the evaluation of promising search directions. The experimental results showed that ReTReK successfully searched synthetic routes based on the specified retrosynthesis knowledge, indicating that the synthetic routes searched with the knowledge were preferred to those without the knowledge. The concept of integrating retrosynthesis knowledge as adjustable parameters into a data-driven CASP application is expected to enhance the performance of both existing data-driven CASP applications and those under development.

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Section: ■ Results and Discussionmentioning

confidence: 96%

AI-Driven Synthetic Route Design Incorporated with Retrosynthesis Knowledge

Ishida

Terayama

Kojima

et al. 2022

J. Chem. Inf. Model.

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“…In the example of Figure 3B, we optimized the penultimate step in our synthesis of umifenovir, 52 an oxidative indolization reaction between 14 and 15 to produce 16. Inspired by the conditions of Glorius, 61 a reaction array was performed using copper catalysts and ligand/additive combinations.…”

Section: Methodsmentioning

confidence: 99%

“…Reaction discovery and library synthesis campaigns utilizing standard 24-, 96-, 384and 1,536-well experiments are described in detail. [50][51][52][53][54][55]…”

Section: Introductionmentioning

confidence: 99%

Rapid Planning and Analysis of High-Throughput Experiment Arrays for Reaction Discovery

Mahjour

Zhang

Shen

et al. 2022

Preprint

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High throughput experimentation (HTE) is an increasingly important tool in reaction discovery. While the hardware for running HTE in the chemical laboratory has evolved significantly in recent years, there remains a need for software solutions to navigate data-rich experiments. Here we have developed phactor™, a software that facilitates the performance and analysis of HTE in a chemical laboratory. phactor™ allows experimentalists to rapidly design arrays of chemical reactions or direct-to-biology experiments in 24, 96, 384, or 1,536 wellplates. Users can access online reagent data, such as a chemical inventory, to virtually populate wells with experiments and produce instructions to perform the reaction array manually, or with the assistance of a liquid handling robot. After completion of the reaction array, analytical results can be uploaded for facile evaluation, and to guide the next series of experiments. All chemical data, metadata, and results are stored in machine-readable formats that are readily translatable to various software formats. We also demonstrate the use of phactor™ in the discovery of several chemistries, including a light-enabled reagent-free sp2–sp2 deaminative–decarboxylative carbon–carbon coupling and a low micromolar inhibitor of the SARS-CoV-2 main protease. Furthermore, phactor™ has been made available for free academic use in 24 and 96 well formats via an online interface.

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“…Given the recent feats of AI approaches in many other areas, the outcome of the “retrosynthesis rivalry” has been somewhat curious and not in AI's favor. On one hand, the success of our “hybrid” expert‐MM‐QM‐ML approach has been documented by multiple experimental validations—by us 21,22,34 and others 35 —of complete, Chematica‐designed reaction routes leading not only to medicinally relevant targets 21,35 (Figure 1a) but also complex natural products, 22,34 at the forefront of modern organic synthesis (Figure 1b). Moreover, in, 22 we showed that world's leading experts were no longer able to distinguish the machine‐planned syntheses of very complex targets from those designed by humans.…”

Section: Introductionmentioning

confidence: 98%

“…Moreover, in, 22 we showed that world's leading experts were no longer able to distinguish the machine‐planned syntheses of very complex targets from those designed by humans. The program, rebranded as Synthia, is now commercialized and deployed by Merck KGaA in industry and academia 35,36 worldwide. On the other hand, the AI‐based efforts have been very prolific in proposing various NN architectures but the synthetic routes they produce continue to be limited to simple targets for which, one could argue, a competent chemist would not really need any computational support.…”

Section: Introductionmentioning

confidence: 99%

Network search algorithms and scoring functions for advanced‐level computerized synthesis planning

Grzybowski

Badowski

Molga

et al. 2022

WIREs Comput Mol Sci

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In 2020, a "hybrid" expert-AI computer program called Chematica (a.k.a. Synthia) was shown to autonomously plan multistep syntheses of complex natural products, which remain outside the reach of purely data-driven AI programs. The ability to plan at this level of chemical sophistication has been attributed mainly to the superior quality of Chematica's reactions rules. However, rules alone are not sufficient for advanced synthetic planning which also requires appropriately crafted algorithms with which to intelligently navigate the enormous networks of synthetic possibilities, score the synthetic positions encountered, and rank the pathways identified. Chematica's algorithms are distinct from prêt-à-porter algorithmic solutions and are product of multiple rounds of improvements, against target structures of increasing complexity. Since descriptions of these improvements have been scattered among several of our prior publications, the aim of the current Review is to narrate the development process in a more comprehensive manner.

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Reinforcing the Supply Chain of Umifenovir and Other Antiviral Drugs with Retrosynthetic Software

Cited by 3 publications

References 17 publications

AI-Driven Synthetic Route Design Incorporated with Retrosynthesis Knowledge

AI-Driven Synthetic Route Design Incorporated with Retrosynthesis Knowledge

Rapid Planning and Analysis of High-Throughput Experiment Arrays for Reaction Discovery

Network search algorithms and scoring functions for advanced‐level computerized synthesis planning

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