English

Multi-Agent Reasoning for Cardiovascular Imaging Phenotype Analysis

Artificial Intelligence 2025-09-09 v2

Abstract

Identifying associations between imaging phenotypes, disease risk factors, and clinical outcomes is essential for understanding disease mechanisms. However, traditional approaches rely on human-driven hypothesis testing and selection of association factors, often overlooking complex, non-linear dependencies among imaging phenotypes and other multi-modal data. To address this, we introduce Multi-agent Exploratory Synergy for the Heart (MESHAgents): a framework that leverages large language models as agents to dynamically elicit, surface, and decide confounders and phenotypes in association studies. Specifically, we orchestrate a multi-disciplinary team of AI agents, which spontaneously generate and converge on insights through iterative, self-organizing reasoning. The framework dynamically synthesizes statistical correlations with multi-expert consensus, providing an automated pipeline for phenome-wide association studies (PheWAS). We demonstrate the system's capabilities through a population-based study of imaging phenotypes of the heart and aorta. MESHAgents autonomously uncovered correlations between imaging phenotypes and a wide range of non-imaging factors, identifying additional confounder variables beyond standard demographic factors. Validation on diagnosis tasks reveals that MESHAgents-discovered phenotypes achieve performance comparable to expert-selected phenotypes, with mean AUC differences as small as 0.004±0.010-0.004_{\pm0.010} on disease classification tasks. Notably, the recall score improves for 6 out of 9 disease types. Our framework provides clinically relevant imaging phenotypes with transparent reasoning, offering a scalable alternative to expert-driven methods.

Keywords

Cite

@article{arxiv.2507.03460,
  title  = {Multi-Agent Reasoning for Cardiovascular Imaging Phenotype Analysis},
  author = {Weitong Zhang and Mengyun Qiao and Chengqi Zang and Steven Niederer and Paul M Matthews and Wenjia Bai and Bernhard Kainz},
  journal= {arXiv preprint arXiv:2507.03460},
  year   = {2025}
}

Comments

accepted by MICCAI 2025

R2 v1 2026-07-01T03:46:34.492Z