Practical Cheminformatics

  Introduction Dataset splitting is one topic that doesn’t get enough attention when discussing machine learning (ML) in drug discovery. The data is typically divided into training and test sets when developing and evaluating an ML model. The model is trained on the training set, and its performance is assessed on the test set. If hyperparameter tuning is required, a validation set is also included. Teams often opt for a simple random split, arbitrarily assigning a portion of the dataset (usually 70-80%) as the training set and the rest (20-30%) as the test set. As many have pointed out, this basic splitting strategy often leads to an overly optimistic evaluation of the model's performance. With random splitting, it's common for the test set to contain molecules that closely resemble those in the training set. To address this issue, many groups have turned to scaffold splits. This splitting strategy, inspired by the work of Bemis and Murcko , reduces each molecule to a scaffold...

  “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...