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AiZynthFinder

License Tests codecov Code style: black version Open In Colab

AiZynthFinder is a tool for retrosynthetic planning. The algorithm is based on a Monte Carlo tree search that recursively breaks down a molecule to purchasable precursors. The tree search is guided by a policy that suggests possible precursors by utilizing a neural network trained on a library of known reaction templates.

An introduction video can be found here: https://youtu.be/r9Dsxm-mcgA

Prerequisites

Before you begin, ensure you have met the following requirements:

  • Linux, Windows or macOS platforms are supported - as long as the dependencies are supported on these platforms.

  • You have installed anaconda or miniconda with python 3.8 - 3.9

The tool has been developed on a Linux platform, but the software has been tested on Windows 10 and macOS Catalina.

Installation

For end-users

First time, execute the following command in a console or an Anaconda prompt

conda create "python>=3.8,<3.10" -n aizynth-env

To install, activate the environment and install the package using pypi

conda activate aizynth-env
python -m pip install aizynthfinder[all]

for a smaller package, without all the functionality, you can also type

python -m pip install aizynthfinder

For developers

First clone the repository using Git.

Then execute the following commands in the root of the repository

conda env create -f env-dev.yml
conda activate aizynth-dev
poetry install -E all

the aizynthfinder package is now installed in editable mode.

Usage

The tool will install the aizynthcli and aizynthapp tools as interfaces to the algorithm:

aizynthcli --config config.yml --smiles smiles.txt
aizynthapp --config config.yml

Consult the documentation here for more information.

To use the tool you need

1. A stock file
2. A trained rollout policy network (including the Keras model and the list of unique templates)
3. A trained filer policy network (optional)

Such files can be downloaded from figshare and here or they can be downloaded automatically using

download_public_data my_folder

where my_folder is the folder that you want download to. This will create a config.yml file that you can use with either aizynthcli or aizynthapp.

Development

Testing

Tests uses the pytest package, and is installed by poetry

Run the tests using:

pytest -v

The full command run on the CI server is available through an invoke command

invoke full-tests

Documentation generation

The documentation is generated by Sphinx from hand-written tutorials and docstrings

The HTML documentation can be generated by

invoke build-docs

Contributing

We welcome contributions, in the form of issues or pull requests.

If you have a question or want to report a bug, please submit an issue.

To contribute with code to the project, follow these steps:

  1. Fork this repository.
  2. Create a branch: git checkout -b <branch_name>.
  3. Make your changes and commit them: git commit -m '<commit_message>'
  4. Push to the remote branch: git push
  5. Create the pull request.

Please use black package for formatting, and follow pep8 style guide.

Contributors

The contributors have limited time for support questions, but please do not hesitate to submit an issue (see above).

License

The software is licensed under the MIT license (see LICENSE file), and is free and provided as-is.

References

  1. Thakkar A, Kogej T, Reymond J-L, et al (2019) Datasets and their influence on the development of computer assisted synthesis planning tools in the pharmaceutical domain. Chem Sci. https://doi.org/10.1039/C9SC04944D
  2. Genheden S, Thakkar A, Chadimova V, et al (2020) AiZynthFinder: a fast, robust and flexible open-source software for retrosynthetic planning. J. Cheminf. https://jcheminf.biomedcentral.com/articles/10.1186/s13321-020-00472-1
  3. Genheden S, Engkvist O, Bjerrum E (2020) A Quick Policy to Filter Reactions Based on Feasibility in AI-Guided Retrosynthetic Planning. ChemRxiv. Preprint. https://doi.org/10.26434/chemrxiv.13280495.v1
  4. Genheden S, Engkvist O, Bjerrum E (2021) Clustering of synthetic routes using tree edit distance. J. Chem. Inf. Model. 61:3899–3907 https://doi.org/10.1021/acs.jcim.1c00232
  5. Genheden S, Engkvist O, Bjerrum E (2022) Fast prediction of distances between synthetic routes with deep learning. Mach. Learn. Sci. Technol. 3:015018 https://doi.org/10.1088/2632-2153/ac4a91

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