English

Hierarchical Variable Importance with Statistical Control for Medical Data-Based Prediction

Machine Learning 2025-08-13 v1 Machine Learning

Abstract

Recent advances in machine learning have greatly expanded the repertoire of predictive methods for medical imaging. However, the interpretability of complex models remains a challenge, which limits their utility in medical applications. Recently, model-agnostic methods have been proposed to measure conditional variable importance and accommodate complex non-linear models. However, they often lack power when dealing with highly correlated data, a common problem in medical imaging. We introduce Hierarchical-CPI, a model-agnostic variable importance measure that frames the inference problem as the discovery of groups of variables that are jointly predictive of the outcome. By exploring subgroups along a hierarchical tree, it remains computationally tractable, yet also enjoys explicit family-wise error rate control. Moreover, we address the issue of vanishing conditional importance under high correlation with a tree-based importance allocation mechanism. We benchmarked Hierarchical-CPI against state-of-the-art variable importance methods. Its effectiveness is demonstrated in two neuroimaging datasets: classifying dementia diagnoses from MRI data (ADNI dataset) and analyzing the Berger effect on EEG data (TDBRAIN dataset), identifying biologically plausible variables.

Keywords

Cite

@article{arxiv.2508.08724,
  title  = {Hierarchical Variable Importance with Statistical Control for Medical Data-Based Prediction},
  author = {Joseph Paillard and Antoine Collas and Denis A. Engemann and Bertrand Thirion},
  journal= {arXiv preprint arXiv:2508.08724},
  year   = {2025}
}
R2 v1 2026-07-01T04:45:43.057Z