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Main Authors: Li, Yizhan, Cloutier, Florence, Wu, Sifan, Parviz, Ali, Knyazev, Boris, Zhang, Yan, Berseth, Glen, Liu, Bang
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.10131
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author Li, Yizhan
Cloutier, Florence
Wu, Sifan
Parviz, Ali
Knyazev, Boris
Zhang, Yan
Berseth, Glen
Liu, Bang
author_facet Li, Yizhan
Cloutier, Florence
Wu, Sifan
Parviz, Ali
Knyazev, Boris
Zhang, Yan
Berseth, Glen
Liu, Bang
contents Generating molecules that satisfy precise numeric constraints over multiple physicochemical properties is critical and challenging. Although large language models (LLMs) are expressive, they struggle with precise multi-objective control and numeric reasoning without external structure and feedback. We introduce \textbf{M olGen}, a fragment-level, retrieval-augmented, two-stage framework for molecule generation under multi-property constraints. Stage I : Prototype generation: a multi-agent reasoner performs retrieval-anchored, fragment-level edits to produce a candidate near the feasible region. Stage II : RL-based fine-grained optimization: a fragment-level optimizer trained with Group Relative Policy Optimization (GRPO) applies one- or multi-hop refinements to explicitly minimize the property errors toward our target while regulating edit complexity and deviation from the prototype. A large, automatically curated dataset with reasoning chains of fragment edits and measured property deltas underpins both stages, enabling deterministic, reproducible supervision and controllable multi-hop reasoning. Unlike prior work, our framework better reasons about molecules by leveraging fragments and supports controllable refinement toward numeric targets. Experiments on generation under two sets of property constraints (QED, LogP, Molecular Weight and HOMO, LUMO) show consistent gains in validity and precise satisfaction of multi-property targets, outperforming strong LLMs and graph-based algorithms.
format Preprint
id arxiv_https___arxiv_org_abs_2601_10131
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle M^4olGen: Multi-Agent, Multi-Stage Molecular Generation under Precise Multi-Property Constraints
Li, Yizhan
Cloutier, Florence
Wu, Sifan
Parviz, Ali
Knyazev, Boris
Zhang, Yan
Berseth, Glen
Liu, Bang
Artificial Intelligence
Multiagent Systems
Generating molecules that satisfy precise numeric constraints over multiple physicochemical properties is critical and challenging. Although large language models (LLMs) are expressive, they struggle with precise multi-objective control and numeric reasoning without external structure and feedback. We introduce \textbf{M olGen}, a fragment-level, retrieval-augmented, two-stage framework for molecule generation under multi-property constraints. Stage I : Prototype generation: a multi-agent reasoner performs retrieval-anchored, fragment-level edits to produce a candidate near the feasible region. Stage II : RL-based fine-grained optimization: a fragment-level optimizer trained with Group Relative Policy Optimization (GRPO) applies one- or multi-hop refinements to explicitly minimize the property errors toward our target while regulating edit complexity and deviation from the prototype. A large, automatically curated dataset with reasoning chains of fragment edits and measured property deltas underpins both stages, enabling deterministic, reproducible supervision and controllable multi-hop reasoning. Unlike prior work, our framework better reasons about molecules by leveraging fragments and supports controllable refinement toward numeric targets. Experiments on generation under two sets of property constraints (QED, LogP, Molecular Weight and HOMO, LUMO) show consistent gains in validity and precise satisfaction of multi-property targets, outperforming strong LLMs and graph-based algorithms.
title M^4olGen: Multi-Agent, Multi-Stage Molecular Generation under Precise Multi-Property Constraints
topic Artificial Intelligence
Multiagent Systems
url https://arxiv.org/abs/2601.10131