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Transfer Learning for Meta-analysis Under Covariate Shift

Machine Learning 2026-04-08 v2 Machine Learning

Abstract

Randomized controlled trials often do not represent the populations where decisions are made, and covariate shift across studies can invalidate standard IPD meta-analysis and transport estimators. We propose a placebo-anchored transport framework that treats source-trial outcomes as abundant proxy signals and target-trial placebo outcomes as scarce, high-fidelity gold labels to calibrate baseline risk. A low-complexity (sparse) correction anchors proxy outcome models to the target population, and the anchored models are embedded in a cross-fitted doubly robust learner, yielding a Neyman-orthogonal, target-site doubly robust estimator for patient-level heterogeneous treatment effects when target treated outcomes are available. We distinguish two regimes: in connected targets (with a treated arm), the method yields target-identified effect estimates; in disconnected targets (placebo-only), it reduces to a principled screen--then--transport procedure under explicit working-model transport assumptions. Experiments on synthetic data and a semi-synthetic IHDP benchmark evaluate pointwise CATE accuracy, ATE error, ranking quality for targeting, decision-theoretic policy regret, and calibration. Across connected settings, the proposed method is best or near-best and improves substantially over proxy-only, target-only, and transport baselines at small target sample sizes; in disconnected settings, it retains strong ranking performance for targeting while pointwise accuracy depends on the strength of the working transport condition.

Keywords

Cite

@article{arxiv.2604.02656,
  title  = {Transfer Learning for Meta-analysis Under Covariate Shift},
  author = {Zilong Wang and Ali Abdeen and Turgay Ayer},
  journal= {arXiv preprint arXiv:2604.02656},
  year   = {2026}
}

Comments

Accepted to IEEE ICHI 2026 Early Bird Track (Oral Presentation)

R2 v1 2026-07-01T11:52:14.485Z