Resolving the bias-precision paradox with stochastic causal representation learning for personalized medicine
Peisong Zhang, Manqiang Peng, Yuxuan Wu, Pawit Phadungsaksawasdi, Wesley Yeung + 19 more
TLDR
sMMD, a stochastic causal representation learning method, resolves the bias-precision paradox in personalized medicine, improving individualized treatment effects.
Key contributions
- Identifies the bias-precision paradox in causal representation learning for individualized treatment effects.
- Introduces sampling-based maximum mean discrepancy (sMMD) for stochastic, subset-level causal alignment.
- Achieves up to 11.5% error reduction and increased recall in two large ICU cohorts (n=27,783).
- Outperforms clinicians and LLMs, improving clinician accuracy by 14.7% and reducing decision time.
Why it matters
This paper addresses a critical challenge in personalized medicine by improving the accuracy and interpretability of individualized treatment effect predictions. Its ability to enhance clinician performance and reduce decision time makes it highly relevant for real-time clinical decision support.
Original Abstract
Estimating individualized treatment effects from longitudinal observational data is central to data-driven medicine, yet existing methods face a fundamental limitation: reducing confounding bias often suppresses clinically informative heterogeneity, degrading patient-specific predictions. Here, we identify this tension as a bias-precision paradox in causal representation learning and introduce sampling-based maximum mean discrepancy (sMMD), a stochastic alignment strategy that replaces global adversarial balancing with subset-level matching. We instantiate this approach in a framework for counterfactual outcome prediction with attribution-grounded interpretability. Across two large-scale ICU cohorts (n = 27,783), our framework improves accuracy under distribution shift, reducing error by up to 11.5% and substantially increasing recall in high-risk tasks. Mechanistic analyses show that sMMD selectively preserves clinically decisive variables. In human-AI evaluation, our method outperforms clinicians-in-training and large language models, and improves clinician accuracy by 14.7% while reducing decision time, enabling interpretable, real-time clinical decision support.
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