Practical Cheminformatics

  “Pay no attention to the man behind the curtain” - The Wizard of Oz Introduction Recently, a few groups have proposed general-purpose large language models (LLMs) like ChatGPT , Claude , and Gemini as tools for generating molecules. This idea is appealing because it doesn't require specialized software or domain-specific model training. One can provide the LLM with a relatively simple prompt like the one below, and it will respond with a list of SMILES strings. You are a skilled medicinal chemist.  Generate SMILES strings for 100 analogs of the molecule represented by the SMILES CCOC(=O)N1CCC(CC1)N2CCC(CC2)C(=O)N. You can modify both the core and the substituents. Return only the SMILES as a Python list. Don’t put in line breaks. Don't put the prompt into the reply. However, when analyzing molecules created by general-purpose LLMs, I'm reminded of my undergraduate Chemistry days. My roommates, who majored in liberal arts, would often assemble random pieces from my mole

  This week is a special Pat substitution.  Pat(rick) Riley  is taking over this blog post for a follow up on our Thompson Sampling paper. In our recent paper  Thompson Sampling─An Efficient Method for Searching Ultralarge Synthesis on Demand Databases  we showed how you could use the classic Thompson Sampling algorithm to select each reagent in a combinatorial library to conduct an efficient search for a variety of scoring functions. Eagle-eyed readers probably noticed that for ROCS, we presented results searching 0.1% of the library and for docking we searched 1% because "docking with TS requires more sampling than ... ROCS". But why is docking harder for a Thompson Sampling based search than ROCS? This post gives an answer to that question. A Visual Version Remember that in Thompson Sampling, for each component in a reaction, you track statistics for each possible reagent. Each reagent is associated with a distribution of scores for complete molecules because the reagent c

I was taken aback by a recent CNBC article entitled “ Generative AI will be designing new drugs all on its own in the near future ”.  I should know better than to pay attention to AI articles in the popular press, but I feel that even scientists working in drug discovery may have a skewed perception of what generative AI can and can’t do.  To understand exactly what’s involved, it might be instructive to walk through a typical generative molecular design workflow and point out a few things.  First, these programs are far from autonomous.  Even when presented with a well-defined problem, generative algorithms produce a tremendous amount of nonsense.  Second, domain expertise is essential when sifting through the molecules produced by a generative algorithm.  Without a significant medicinal chemistry background, one can’t make sense of the results.  Third, while a few nuggets exist in the generative modeling output, a lot of work and good old-fashioned cheminformatics are required to ext