English

Improving Image-Based Precision Medicine with Uncertainty-Aware Causal Models

Machine Learning 2023-08-11 v4

Abstract

Image-based precision medicine aims to personalize treatment decisions based on an individual's unique imaging features so as to improve their clinical outcome. Machine learning frameworks that integrate uncertainty estimation as part of their treatment recommendations would be safer and more reliable. However, little work has been done in adapting uncertainty estimation techniques and validation metrics for precision medicine. In this paper, we use Bayesian deep learning for estimating the posterior distribution over factual and counterfactual outcomes on several treatments. This allows for estimating the uncertainty for each treatment option and for the individual treatment effects (ITE) between any two treatments. We train and evaluate this model to predict future new and enlarging T2 lesion counts on a large, multi-center dataset of MR brain images of patients with multiple sclerosis, exposed to several treatments during randomized controlled trials. We evaluate the correlation of the uncertainty estimate with the factual error, and, given the lack of ground truth counterfactual outcomes, demonstrate how uncertainty for the ITE prediction relates to bounds on the ITE error. Lastly, we demonstrate how knowledge of uncertainty could modify clinical decision-making to improve individual patient and clinical trial outcomes.

Keywords

Cite

@article{arxiv.2305.03829,
  title  = {Improving Image-Based Precision Medicine with Uncertainty-Aware Causal Models},
  author = {Joshua Durso-Finley and Jean-Pierre Falet and Raghav Mehta and Douglas L. Arnold and Nick Pawlowski and Tal Arbel},
  journal= {arXiv preprint arXiv:2305.03829},
  year   = {2023}
}
R2 v1 2026-06-28T10:27:22.731Z