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Chemical Language Model Linker: Blending Text and Molecules with Modular Adapters.

Yifan Deng1,2, Spencer S Ericksen3, Anthony Gitter1,2,4

  • 1Department of Computer Sciences, University of Wisconsin-Madison, Madison, Wisconsin 53706, United States.

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This summary is machine-generated.

We introduce ChemLML, a lightweight adapter method for generating molecules from text. This approach efficiently leverages pretrained models, outperforming training from scratch and enabling practical applications like drug discovery.

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Area of Science:

  • Computational chemistry
  • Artificial intelligence
  • Drug discovery

Background:

  • Large language models (LLMs) and multimodal models offer potential for generating novel molecules from text descriptions.
  • Current multimodal models often require training from scratch, which is computationally expensive and limits scalability.
  • Existing methods do not effectively leverage high-quality pretrained models for this task.

Purpose of the Study:

  • To propose a novel, lightweight adapter-based strategy named Chemical Language Model Linker (ChemLML) for conditional molecular generation from text.
  • To enable the use of diverse pretrained text models for molecule generation without extensive retraining.
  • To investigate the impact of molecular representations (SMILES vs. SELFIES) on generation performance.

Main Methods:

  • Developed ChemLML, an adapter-based strategy that links pretrained text and molecular domain models.
  • Trained relatively few adapter parameters to tailor existing text models for molecule generation.
  • Evaluated performance using a filtered PubChem dataset and compared SMILES and SELFIES representations.
  • Generated candidate protein inhibitors and membrane-permeable molecules for practical demonstration.

Main Results:

  • ChemLML effectively blends pretrained single-domain models for conditional molecular generation.
  • The choice of molecular representation significantly impacts generation performance, with SMILES often being preferable.
  • Identified issues with the standard PubChem dataset for evaluation and provided a refined test set.
  • Successfully generated candidate molecules with potential therapeutic and pharmacokinetic properties.

Conclusions:

  • ChemLML offers an efficient and scalable approach to text-to-molecule generation by leveraging pretrained models.
  • Molecular representation choice is critical for successful conditional generation.
  • The developed method and dataset facilitate practical applications in drug discovery and molecular design.