Multi-objective generative AI for designing novel brain-targeting small molecules

TL;DR

This paper presents a multi-objective generative AI approach to design novel, BBB-permeable small molecules targeting the D2 receptor, balancing permeability, safety, and binding affinity for CNS drug discovery.

Contribution

It introduces a multi-objective AI framework combining graph neural networks and Monte Carlo Tree Search to generate diverse, synthesizable molecules with desired CNS drug properties.

Findings

Generated 26,581 novel molecules with high predicted BBB permeability.

Top candidates show binding affinity comparable to risperidone.

Validated molecules via molecular docking simulations.

Abstract

The strict selectivity of the blood-brain barrier (BBB) represents one of the most formidable challenges to successful central nervous system (CNS) drug delivery. Computational methods to generate BBB permeable drugs in silico may be valuable tools in the CNS drug design pipeline. However, in real-world applications, BBB penetration alone is insufficient; rather, after transiting the BBB, molecules must bind to a specific target or receptor in the brain and must also be safe and non-toxic. To discover small molecules that concurrently satisfy these constraints, we use multi-objective generative AI to synthesize drug-like BBB-permeable small molecules. Specifically, we computationally synthesize molecules with predicted binding affinity against dopamine receptor D2, the primary target for many clinically effective antipsychotic drugs. After training several graph neural network-based property predictors, we adapt SyntheMol (Swanson et al., 2024), a recently developed Monte Carlo Tree Search-based algorithm for antibiotic design, to perform a multi-objective guided traversal over an easily synthesizable molecular space. We design a library of 26,581 novel and diverse small molecules containing hits with high predicted BBB permeability and favorable predicted safety and toxicity profiles, and that could readily be synthesized for experimental validation in the wet lab. We also validate top scoring molecules with molecular docking simulation against the D2 receptor and demonstrate predicted binding affinity on par with risperidone, a clinically prescribed D2-targeting antipsychotic. In the future, the SyntheMol-based computational approach described here may enable the discovery of novel neurotherapeutics for currently intractable disorders of the CNS.