E(3)-Equivariant Models Cannot Learn Chirality: Field-Based Molecular Generation
Abstract
Obtaining the desired effect of drugs is highly dependent on their molecular geometries. Thus, the current prevailing paradigm focuses on 3D point-cloud atom representations, utilizing graph neural network (GNN) parametrizations, with rotational symmetries baked in via E(3) invariant layers. We prove that such models must necessarily disregard chirality, a geometric property of the molecules that cannot be superimposed on their mirror image by rotation and translation. Chirality plays a key role in determining drug safety and potency. To address this glaring issue, we introduce a novel field-based representation, proposing reference rotations that replace rotational symmetry constraints. The proposed model captures all molecular geometries including chirality, while still achieving highly competitive performance with E(3)-based methods across standard benchmarking metrics.
Cite
Text
Dumitrescu et al. "E(3)-Equivariant Models Cannot Learn Chirality: Field-Based Molecular Generation." International Conference on Learning Representations, 2025.Markdown
[Dumitrescu et al. "E(3)-Equivariant Models Cannot Learn Chirality: Field-Based Molecular Generation." International Conference on Learning Representations, 2025.](https://mlanthology.org/iclr/2025/dumitrescu2025iclr-equivariant/)BibTeX
@inproceedings{dumitrescu2025iclr-equivariant,
title = {{E(3)-Equivariant Models Cannot Learn Chirality: Field-Based Molecular Generation}},
author = {Dumitrescu, Alexandru and Korpela, Dani and Heinonen, Markus and Verma, Yogesh and Iakovlev, Valerii and Garg, Vikas and Lähdesmäki, Harri},
booktitle = {International Conference on Learning Representations},
year = {2025},
url = {https://mlanthology.org/iclr/2025/dumitrescu2025iclr-equivariant/}
}