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Particles in a solid are tightly packed together (fixed shape) and often arranged in a regular pattern; in a liquid, they are close together with no regular arrangement (no fixed shape); in a gas, they are far apart with no regular arrangement (no fixed shape). Particles in a solid vibrate about fixed positions (cannot flow) and do not generally move in relation to one another; in a liquid, they move past each other (can flow) but remain in essentially constant contact; in a gas, they move...
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OTMol: Robust Molecular Structure Comparison via Optimal Transport.

Xiaoqi Wei1, Xuhang Dai2, Yaqi Wu3

  • 1Department of Mathematics, North Carolina State University, Raleigh, North Carolina 27695, United States.

Journal of Chemical Information and Modeling
|October 8, 2025
PubMed
Summary
This summary is machine-generated.

We introduce OTMol, a novel method using optimal transport for molecular alignment. OTMol accurately matches atoms, preserving chemical features like chirality, for reliable structural comparisons.

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Area of Science:

  • Computational chemistry
  • Structural bioinformatics
  • Machine learning in chemistry

Background:

  • Root-mean-square deviation (RMSD) is crucial for molecular structural similarity assessment.
  • Traditional RMSD methods struggle with atom ordering, cluster configurations, and chirality.
  • Existing alignment algorithms often fail to generalize across diverse chemical systems.

Purpose of the Study:

  • To develop a robust and generalizable molecular alignment method.
  • To overcome limitations of traditional RMSD calculations, including atom correspondence issues.
  • To leverage intrinsic molecular information for accurate structural comparisons.

Main Methods:

  • Formulated molecular alignment as a fused supervised Gromov-Wasserstein (fsGW) optimal transport problem.
  • Utilized intrinsic geometric and topological relationships within molecules for data-driven matching.
  • Ensured one-to-one atom mappings to maintain molecular integrity.

Main Results:

  • OTMol achieves low RMSD values across diverse systems like ATP, imatinib, lipids, peptides, and water clusters.
  • The method preserves crucial chemical features, including molecular chirality and bond connectivity.
  • OTMol demonstrates computational efficiency and avoids erroneous many-to-one alignments in clusters.

Conclusions:

  • Optimal transport theory provides a powerful framework for molecular alignment.
  • OTMol offers a principled, data-driven approach superior to heuristic methods.
  • This method advances structural comparison in cheminformatics and molecular modeling.