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Main Authors: Wa, Shiyun, Wang, Yifei, Sciabola, Simone, Wang, Ye
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.24474
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author Wa, Shiyun
Wang, Yifei
Sciabola, Simone
Wang, Ye
author_facet Wa, Shiyun
Wang, Yifei
Sciabola, Simone
Wang, Ye
contents Molecular similarity plays a central role in ligand-based drug discovery, such as virtual screening, analog searching, and goal-directed molecular generation. However, traditional similarity measures, ranging from fingerprint-based Tanimoto coefficients to 3D shape overlays, are often computationally expensive at scale or rely on hand-crafted molecular descriptors. Meanwhile, many deep learning approaches to similarity-aware design still depend on similarity-specific supervision or costly data curation, limiting their generality across targets. In this work, we propose pretrained embedding distance (PED) as an effective alternative, computed directly from pretrained molecular models without task-specific training. Experimental results show that PED exhibits distinct correlations with traditional similarity metrics, and performs effectively in both ranking molecules for virtual screening and guiding molecular generation via reward design. These findings suggest that pretrained molecular embeddings capture rich structural information and can serve as a promising and scalable similarity measurement for modern AI-aided drug discovery.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24474
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Advancing Ligand-based Virtual Screening and Molecular Generation with Pretrained Molecular Embedding Distance
Wa, Shiyun
Wang, Yifei
Sciabola, Simone
Wang, Ye
Machine Learning
Molecular similarity plays a central role in ligand-based drug discovery, such as virtual screening, analog searching, and goal-directed molecular generation. However, traditional similarity measures, ranging from fingerprint-based Tanimoto coefficients to 3D shape overlays, are often computationally expensive at scale or rely on hand-crafted molecular descriptors. Meanwhile, many deep learning approaches to similarity-aware design still depend on similarity-specific supervision or costly data curation, limiting their generality across targets. In this work, we propose pretrained embedding distance (PED) as an effective alternative, computed directly from pretrained molecular models without task-specific training. Experimental results show that PED exhibits distinct correlations with traditional similarity metrics, and performs effectively in both ranking molecules for virtual screening and guiding molecular generation via reward design. These findings suggest that pretrained molecular embeddings capture rich structural information and can serve as a promising and scalable similarity measurement for modern AI-aided drug discovery.
title Advancing Ligand-based Virtual Screening and Molecular Generation with Pretrained Molecular Embedding Distance
topic Machine Learning
url https://arxiv.org/abs/2604.24474