English

An Artifact-based Agent Framework for Adaptive and Reproducible Medical Image Processing

Artificial Intelligence 2026-04-27 v1 Computer Vision and Pattern Recognition Multiagent Systems

Abstract

Medical imaging research is increasingly shifting from controlled benchmark evaluation toward real-world clinical deployment. In such settings, applying analytical methods extends beyond model design to require dataset-aware workflow configuration and provenance tracking. Two requirements therefore become central: \textbf{adaptability}, the ability to configure workflows according to dataset-specific conditions and evolving analytical goals; and \textbf{reproducibility}, the guarantee that all transformations and decisions are explicitly recorded and re-executable. Here, we present an artifact-based agent framework that introduces a semantic layer to augment medical image processing. The framework formalizes intermediate and final outputs through an artifact contract, enabling structured interrogation of workflow state and goal-conditioned assembly of configurations from a modular rule library. Execution is delegated to a workflow executor to preserve deterministic computational graph construction and provenance tracking, while the agent operates locally to comply with most privacy constraints. We evaluate the framework on real-world clinical CT and MRI cohorts, demonstrating adaptive configuration synthesis, deterministic reproducibility across repeated executions, and artifact-grounded semantic querying. These results show that adaptive workflow configuration can be achieved without compromising reproducibility in heterogeneous clinical environments.

Keywords

Cite

@article{arxiv.2604.21936,
  title  = {An Artifact-based Agent Framework for Adaptive and Reproducible Medical Image Processing},
  author = {Lianrui Zuo and Yihao Liu and Gaurav Rudravaram and Karthik Ramadass and Aravind R. Krishnan and Michael D. Phillips and Yelena G. Bodien and Mayur B. Patel and Paula Trujillo and Yency Forero Martinez and Stephen A. Deppen and Eric L. Grogan and Fabien Maldonado and Kevin McGann and Hudson M. Holmes and Laurie E. Cutting and Yuankai Huo and Bennett A. Landman},
  journal= {arXiv preprint arXiv:2604.21936},
  year   = {2026}
}
R2 v1 2026-07-01T12:32:53.955Z